In modern manufacturing, in order to meet the increasing demand for workpiece processing accuracy and efficiency, various innovative processing technologies continue to emerge. Among them, pipe joint turning and milling composite precision processing technology, as a composite processing technology that combines turning and milling, is becoming a new favorite in the manufacturing industry.

1. Technical principles

The combined precision machining technology of pipe joint turning and milling is an efficient processing technology that combines turning and milling. By installing turning and milling tools on the same machine tool and utilizing the machine tool's multi-axis control system, multiple machining processes can be completed on the same workbench. This technology combines the advantages of turning and milling to achieve efficient machining of complex workpieces.

2. Technical advantages

Traditional turning and milling usually require different machine tools for processing, but the combined precision machining technology of pipe joint turning and milling can complete multiple processing procedures on the same machine tool, making full use of equipment resources and improving production efficiency.

Composite machining technology can make the tool's machining angles in different directions more flexible, thereby achieving more precise machining. This improvement in accuracy can not only reduce subsequent processing steps, but also avoid an increase in the scrap rate caused by insufficient accuracy, improving the overall processing quality.

By merging the turning and milling processes together, the tool and clamp changing time during the machining process can be reduced, the machining cycle can be shortened, and the production efficiency can be improved.

Pipe joint turning and milling composite precision processing technology has been widely used in aerospace, automobile manufacturing, machinery manufacturing and other fields. For example, in the aerospace field, composite processing technology can be used to process aerospace parts with various complex structures, improving the processing accuracy and quality of parts and meeting the requirements for high precision and lightweight of aerospace products.