China shandong lu young machinery co.,ltd Company Cases

Our workers packing vertical machining center and plan to ship vmc855 machine to our customers. This milling machine is equipped with Siemens828d control system and 250mm Taiwan brand 4 axis.

        The five-axis machining center processes impellers through a complex and precise process, involving the following key techniques and steps: Design and Modeling: First, a 3D model of the impeller is created using CAD software (such as UG, CATIA, or PRO/E) based on specific design requirements, including blade shapes, root designs, and any special features like deep narrow channels, large twist angles, or variable root radii. Programming: The design model is then converted into machining paths using CAD/CAM software (like UG), generating a five-axis machining program. This step involves precise tool path calculations to ensure safe and efficient contact between the tool and the impeller's surface. Tool Path Planning: Considering the impeller's complex geometry, the tool path is meticulously planned to avoid collisions between the tool and the impeller walls while maintaining accuracy and surface quality. This includes strategies for tool entry and exit, cutting angles, and feed rates. Machine Setup: The five-axis machining center is prepared, including installing the appropriate tooling, calibrating the five axes (X, Y, Z, A, C) for accuracy, and setting up an effective cooling system to ensure stable and safe machining. Processing: Under program control, the machining center executes the pre-programmed paths, precisely cutting the impeller blank through coordinated motion of the spindle and additional rotary axes. Monitoring and Adjustment: During the process, the operator closely monitors the machine's status and machining results, making real-time adjustments as needed to ensure accuracy and quality. Post-Processing and Quality Inspection: After machining, the impeller might undergo surface treatment, like painting, and undergo rigorous quality checks, including dimension accuracy, surface roughness, and dynamic balance tests, to confirm it meets design specifications. Data Optimization and Feedback: Based on the machining outcome, programming or process parameters may be optimized, creating a continuous improvement loop to enhance subsequent impeller machining efficiency and quality. Batch Production: Once the process is stable, the five-axis machining center can produce in batches, supplying high-performance, monolithic impellers for turbomachinery in the aerospace and other industries. With technological advancements, latest technologies like linear motors, torque motors, high-speed spindles, and advanced control systems are often employed to boost machining speed, accuracy, and surface finish.    

vertical machinging center VMC1160 4 axis processing metal parts        The main features of a four-axis machining center include: Increased Freedom of Movement: A four-axis machining center adds a rotational axis (usually referred to as the A, B, or C axis) to the standard three axes (X, Y, Z), allowing for multi-angle machining and expanding the scope of work. Processing Complex Components: It enables the handling of more complex parts, such as curved surfaces, helical grooves, and turbine blades, completing multiple aspects and intricate shapes in a single setup, enhancing precision and efficiency. Reduced Clamping times: With the ability to machine from multiple angles, the need for re-clamping is minimized, reducing errors associated with repeated setups and maintaining machining accuracy. Improved Production Efficiency: By performing multiple operations in one setup, four-axis machining centers shorten production cycles, enhancing efficiency, especially for batch production. Cost Savings: It reduces setup and adjustment times, as well as potential scrap rates from multiple clamping, leading to cost savings in the long run. High Automation Level: Often equipped with an automatic tool changer, four-axis machining centers can operate continuously without human intervention, further boosting productivity. Flexibility: They cater to various machining requirements and are highly adaptable, making them particularly useful in industries that require the production of complex geometries, such as aerospace, automotive, and mold manufacturing. These features of a four-axis machining center grant it significant advantages in precision manufacturing and the production of intricate components.