CNC machining is a process method for machining parts on CNC machine tools. It controls the displacement of parts and tools through digital information to achieve mechanical machining. CNC machining solves the problems of variable parts variety, small batch, complex shape, high precision requirements, etc., and is an effective way to achieve efficient and automated machining.
The basic principle of CNC machining is to issue instructions through the control system to make the tool move according to the predetermined program to complete the machining of the workpiece. This processing method relies on computer technology and modern control technology, making mechanical machining more precise and efficient. The movement and auxiliary actions of CNC machine tools are all controlled by the instructions issued by the CNC system, thus achieving a high degree of automation and intelligence.
CNC machining has a wide range of applications: automotive parts manufacturing; drone parts manufacturing; medical equipment parts; medical industry products; robot parts; automation equipment parts; injection mold parts; die-casting mold parts, etc. CNC machining can be used for processing or production related to metal parts.
CNC machining can be divided into: CNC turning and CNC milling.
CNC turning: the workpiece rotates, and the turning tool moves along a straight line or curve. Below is a picture of a CNC lathe:
CNC milling: the milling cutter rotates, and the milling cutter moves along a straight line or curve. Below is a picture of a CNC milling machine:
In order to have a deeper understanding of the charm of CNC machining, I will learn about it through pictures and videos of a "impeller" product processed in our factory: The processing of "impeller" is considered a medium-difficulty product in CNC processing. Because it requires a "5-axis CNC engraving machine" to process。 The following picture shows the "Three-dimension measuring instrument" measuring its data.
ndustrial molding is a manufacturing process in which molten materials are injected into a mold cavity under high pressure and then cooled and solidified to mass-produce highly consistent components. This article focuses on advantages of injection molding and plastic mold design, outlining the industry advantages, process highlights, and typical applications to help you fully understand the value and practices of industrial molding.
This article introduces five common types of plastic moulding processes systematically, elaborates on the advantages of injection molding, and focuses on the features and application scenarios of high precision plastic injection molding and services by low volume injection molding companies, providing practical guidance for selecting the best plastic moulding solutions on Vanmodel.
In the medical industry, products demand extremely high precision and quality. Medical injection molding has become the preferred process for manufacturing medical devices due to its excellent dimensional accuracy and consistency. Through medical injection molding, complex structures and tight tolerance requirements can be easily achieved, significantly enhancing the performance and reliability of medical devices, especially in applications requiring high precision plastic injection molding.
In today’s automotive manufacturing industry, injection molding for automotive parts has become one of the essential core processes. As demands for lightweight construction, high performance, and complex structures increase, automotive component manufacturers are increasingly relying on efficient, precise automotive injection technologies. Vanmodel, leveraging deep experience and advanced equipment, is dedicated to providing customers with high-quality molds and custom part solutions.
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types of plastic moulding process
Benefits of Medical Injection Molding | High Precision Medical Device Molding
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