To everyone's relief, the market appears to be on the road to recovery. It is also fortunate that it is the case. Despite a drop in production, there was not a corresponding reduction in the number of automobiles sold, which resulted in a limited supply and an increased demand. The years 2021 through 2023 are expected to see an even more significant increase in sales of personal automobiles, particularly sport utility vehicles (SUVs) and pickup trucks in the United States. CNC machining is relied on by manufacturers not only to fulfill this demand but also to continue producing the most technologically advanced and safest automobiles.
Why is computer numerically controlled (CNC) machining used in the automotive industry?
Because manufacturers need to redesign their products at an ever-quicker pace in order to maintain their market share, they are shifting toward high-mix, low-volume production and developing increasingly specialized, extremely complicated components. While doing so, one of their primary concerns is in trying to keep the vehicle's body weight to a minimum without compromising its structural soundness or overall level of safety. In many cases, this calls for the machining of "difficult" materials, which are materials that are prone to warping or fracturing when they are being machined. Aluminum and various other lightweight materials are typically utilized in the production of automobiles. Polymethyl methacrylate (PMMA) acrylic is a shatter-resistant alternative to standard glass that is used for lighting fixtures. This material, which presents its own unique challenges when it comes to machining, is relatively new to the industry. In addition, manufacturers are becoming aware of the growing demand for luxury technologies in their passenger vehicles. These technologies require specialized electronic components that have extremely precise tolerances.
Without computer numerical control (CNC) machining, which eliminates the need for parts to be manually machined, it would be nearly impossible to meet these tolerances while still preserving the material's integrity. It is especially important to the repeatability and timeliness of production, both of which are essential to the industry that was responsible for the invention of the assembly line. Automated computer numerical control (CNC) machining requires the operators of the machines to do nothing more than set up the material and press the start button.
What kinds of applications are there?
Machining processes such as milling and mill-turning are utilized most frequently in the production of vehicles. These methods are utilized by manufacturers in the production of a wide variety of goods, including driveshafts, components for suspension systems, cylinder heads, exhaust systems, molds for various parts, and many more. If the machining code is precise enough, the entire engine block can be machined from a single large piece of aluminum. The same level of precision can produce components as minute as valve retainers and bushings. The production of electric vehicles (EVs), which is expected to account for 25 percent of the world's vehicle production by the year 2030, is an industry that can benefit greatly from CNC machining . The production of electric vehicles makes extensive use of 3D printing; however, in order to achieve the tolerances necessary for a safe and efficient vehicle, the printed parts must first be CNC machined to the appropriate specifications.
What are the advantages of using computer-aided manufacturing (CAM) software?
The bottom line is that in order for automotive manufacturers to maintain their competitive edge, they need to combine their use of CNC machining with CAM software. Due to recent bottlenecks in the supply chain, rising numbers of vehicle sales, and ongoing improvements in safety measures, accuracy and speed have assumed a position of utmost significance. Writing G-code manually makes it impossible to achieve such a level of productivity. Manufacturers can put their faith in their software to figure out the most efficient way to machine their components if they are using a sophisticated CAM system. These systems will come equipped with technology that simulates both the finished product and the machining process, eliminates gouges and warping during machining, and ensures quality even at the highest feeds and speeds possible.