CNC Machine Tools News

Next generation compact 5-axis vertical machining center - the Mazak VARIAXIS C-600

Yamazaki Mazak has unveiled a new high-accuracy simultaneous 5-axis vertical machining centre, the Mazak VARIAXIS C-600, suitable for a wide range of industry sectors, including the aerospace and automotive markets.

Mazak Variaxis C 600 

The Mazak VARIAXIS C-600, which is the successor machine to the highly successful Mazak VARIAXIS j-600/5X, is being marketed at an attractive price point to provide a high performance and cost-effective 5-axis solution.

The Mazak VARIAXIS C-600 is characterised by its highly agile performance, with no compromise on rigidity. The compact machine, capable of machining workpieces up to Ø730 mm x H450 mm and 500 kg in weight, has been designed with a large machining envelope and a high-rigidity structure featuring a Ø600 mm fully supported trunnion table with roller gear cam on the B- and C-axes. Exceptional high-speed performance is delivered with 42 m/min rapid traverse rates in the X-,Y- and Z-axes, and a chip-to-chip time of just 4.5 seconds to reduce non-cutting time for faster cycle times.

Most importantly, the new Mazak VARIAXIS C-600 comes with a class-leading range of specification options, enabling users to configure the cnc machine tool to match their specific application.

The machine’s high-rigidity spindle can perform heavy-duty cutting of steel, as well as the high-speed machining of other non-ferrous materials such as aluminium, as it can be configured with four different spindle options. These range from a 12,000 rpm standard spindle, up to 15,000 rpm high-torque option, or 18,000 rpm high-speed and 20,000 rpm high-power spindles. In addition, the new Mazak VARIAXIS C-600 features a 30-tool magazine as standard, complete with double arm automatic tool changer which can drastically reduce chip-to-chip times. Alongside this standard specification, 60, 90 and 120 tool magazine options also available.

The Mazak VARIAXIS C-600 also employs Mazak’s SmoothAi Spindle function, featuring AI adaptive control (patent pending) that suppresses milling spindle chatter by intelligently adjusting cutting technology based on feedback from sensors built into the machine.

The modularity of the Mazak VARIAXIS C-600 also extends to the variety of coolant packages that are available for different applications up to 70 bar pressure. Dedicated cast iron, aluminium and composite, and casting machining packages are also available as options.

As well as offering excellent operator access and ergonomics, the Mazak VARIAXIS C-600 has been designed to integrate easily with a range of automation solutions, such as MPP and Palletech. Optional extras such as a side loading door, and preparation for hydraulic and pneumatic fixture interfaces are also available to support bespoke automation projects with articulated robots. Integration of automation is further enhanced with the new Smooth RCC (Robot Cell Controller) adding advanced capabilities, such as tool and fixture capability check, tool set-up and fixture set-up, while the Robot Setup Assist enables efficient programming of the robot in the same co-ordinate system as the machine.

The latest Mazak VARIAXIS C-600 is equipped with SmoothAi, Mazak’s new artificial intelligence control, which has in-built learning capability to continually improve machine performance. Smooth Machining Configuration Plus allows operators to easily adjust features including cycle time, finished surface and machined shape on the CNC display according to material requirements. This is especially effective for complex workpieces with contours defined in small program increments. Specific settings can be saved and stored to allow them to be easily used for future cycles.

The Smooth Project Manager also allows for easy management of data required to execute machining programs such as tool data, fixtures, coordinates, parameters and workpiece 3D models. Further machining accuracy is guaranteed by the new Ai Thermal Shield function, which uses algorithms to automatically determine the volume of compensation needed according to changes in temperature.