The purpose of CNC machining
CNC machining plays an important role in various fields of manufacturing, providing high-precision, high-efficiency, and flexible machining solutions, driving the development and innovation of the manufacturing industry.
1. CNC machining is repeatable
CNC machining is a repeatable manufacturing process. CNC stands for computer numerical control, which uses pre programmed computer instructions to control machine tools and tools, accurately cutting, carving, punching, or processing various materials. Compared to manual operations, CNC machining has many advantages, one of which is its ability to produce highly accurate and consistent parts.
By using computer-controlled machine tools and tools, a high degree of automation and accuracy can be achieved. Once appropriate processing procedures and process parameters are established, the same operation can be repeated to produce the same results. It can reduce the risk of human errors and operational errors, improve production efficiency and speed. At the same time, CNC machining can also handle complex geometric shapes and design requirements, making production more flexible and diverse.
2. Dental equipment
CNC machining has a wide range of applications and services in the field of dental equipment. Especially for dental implants, CNC machining can manufacture dental implants, including the implant body and threaded parts. Through CNC processing, high-precision processing is achieved to ensure the fit and stability between the implant and the patient's oral cavity.
By using CNC machining with high precision and efficiency, ceramic restorations such as crowns and braces that meet the anatomical structure and aesthetic requirements of patients' oral cavity are manufactured. It also plays an important role in the manufacturing of dental molds. For example, molds for dental braces or braces can be customized and manufactured through CNC machining to ensure their fit and comfort with the patient's mouth.
CNC machining can also manufacture various components in dental equipment, such as handles, fixtures, guide rails, etc. It can meet the customization needs of different devices.
3. Mold manufacturing
CNC machining is used to manufacture various types of molds, such as injection molds, die-casting molds, stamping molds, etc. Through CNC machining, precise cutting, milling, and punching of various parts of the mold ensures dimensional accuracy and geometric consistency of the mold. CNC machining has high-precision machining capabilities, achieving micron level or even higher precision machining requirements. For mold manufacturing, it is crucial because the accuracy and quality of the mold directly affect the quality of the final product.
CNC machining can achieve the processing of complex surfaces, including 3D curves, irregular surfaces, etc. By using functions such as multi axis linkage and tool radius compensation, complex mold geometries can be accurately cut and carved. Rapid manufacturing of molds. Customized processing according to design requirements to adapt to mold manufacturing of different shapes, sizes, and materials. By modifying the processing program and process parameters, customized manufacturing of different molds can be achieved.
CNC machining achieves automation and intelligence of the machining process through connection with computer systems. Realize functions such as automatic tool change, automatic measurement, and automatic deviation correction, improving processing efficiency and consistency.
4. Carving and Sculpture
CNC machining has high-precision processing capabilities, achieving fine carving details and complex surface shapes. By using precision cutting tools and multi axis linkage, micro level or even higher precision engraving requirements can be achieved. Realize the processing and carving of complex shapes, including curves, surfaces, bumps, etc. By using CAD/CAM software and CNC programming, designers convert complex artistic shapes into CNC machining codes and achieve precise machining.
CNC machining can reduce production cycles, improve production efficiency, and achieve large-scale mass production for manufacturers and studios. Suitable for carving and sculpture of various materials, including wood, metal, plastic, stone, etc. By selecting appropriate cutting tools and processing parameters, it can adapt to the processing requirements of different materials and achieve the combination of multiple materials.
By saving and re calling the machining program, CNC machining can repeatedly produce the same carving work, ensuring consistency and quality. Allow designers to make real-time modifications and adjustments during the production process. By modifying the processing program, the details, shapes, and dimensions of carving can be quickly adjusted to achieve flexible design and customization.
5. Electronic manufacturing
CNC machining can be used to manufacture printed circuit boards (PCBs). By using CNC milling and drilling machines to accurately cut, mill, and punch PCBs, create circuit board substrates for electronic products. Capable of achieving micron level processing requirements. In electronic manufacturing, precise device installation, welding, and assembly are crucial to ensure the performance and reliability of electronic products.
CNC machining is used to manufacture various parts and components in electronic products, such as shells, connectors, switches, etc. By using CNC machining to accurately cut, mill, and punch these parts, the design requirements of electronic products are met. Has efficient processing capabilities for rapid manufacturing of electronic products.
CNC machining is customized according to design requirements to meet the shape, size, and functional requirements of different electronic products. By modifying processing programs and process parameters, customized manufacturing of different electronic products can be achieved. By connecting with computer systems, the automation and intelligence of the processing process can be achieved. Realize functions such as automatic tool change, automatic measurement, and automatic deviation correction, improving processing efficiency and consistency.
6. Transportation
CNC machining is applied to the body manufacturing of vehicles such as automobiles, trains, and airplanes. By using CNC cutting, milling, and forming to accurately process body panels and achieve consistency in appearance and dimensions, the quality and safety of the body structure can be ensured.
CNC machining is used in the transportation industry to manufacture engines and engine components. By using CNC milling machines, lathes, and drilling machines, precision engine parts such as cylinder blocks, crankshafts, valves, etc. are processed and manufactured to ensure the performance and reliability of the engine. Manufacturing braking and suspension system components for vehicles. By using CNC machining, high-precision brake discs, brake calipers, suspension arms and other components are produced to achieve precise braking and suspension performance.
CNC machining is used to manufacture wheel hub and tire components. By using CNC milling machines and lathes, the shape, aperture, and thread of the wheel hub, as well as the connection structure of tire components, are processed to meet the tire installation requirements of transportation vehicles.
CNC machining also has important applications in the aerospace field. By using CNC machining, various structures and components of transportation vehicles such as airplanes, helicopters, and rockets can be manufactured, such as wing plates, wings, engine casings, etc., to meet the high-precision and high reliability requirements of aerospace.