New machine combines 3D printing and machining

New machine combines 3D printing and machining

Metal Powder Report  Volume 00, Number 00  March 2015 ADDITIVE MANUFACTURING Additive Manufacturing New machine combines 3D printing and machining...

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Metal Powder Report  Volume 00, Number 00  March 2015

ADDITIVE MANUFACTURING

Additive Manufacturing New machine combines 3D printing and machining Hermle, a German machine tool manufacturer, has integrated AM capability into a 5axis machining center. The production of 3D metal components can involve an energy intensive laser to melt and fuse successive layers of powder. In contrast, Hermle’s MPA (metal powder application) thermal spray process is based on lower energy kinetic compacting, or micro-forging, the company says. The new hybrid machine, known as an MPA 40, comprises a 5-axis C 40 U machining center with a powder application nozzle mounted alongside the vertical milling spindle and a heater built into the 4th/ 5th axis rotary swiveling table.

Micro-forging A production cycle involves clamping an application-specific faceplate onto the rotary table, importing the CAD model of the component to be produced, and converting the 3D data into successive micro-forging and milling cycles, which can be followed by water quenching and heat treatment, if necessary. A high-energy jet of super-heated steam propels metal powder suspended in nitrogen through a Laval nozzle onto a substrate at three times the speed of sound. The impact creates local pressures of 10 GPa and temperatures up to 10008C. The result is localized super-plastic deformation, forging the powder particles together and onto the component surface. The fully dense, bonded layer is machined by metalcutting using up to five CNC axes, followed by deposition of a further layer. The process

A Hermle MPA 40 hybrid 5-axis machining center with integrated additive manufacturing capability, sound insulating cabinet and control panel.

is repeated any number of times to produce the required component. Powder grain size is between 25 and 75 microns and deposition rate for tool steel, for example, is 4–5 cm3/min. Micro-forging allows dissimilar metals to be layered, with either a sharp or a smooth transition between them. Up to six materials can be made available, stored in sealed drums within the machine. Each metal powder requires its own process parameters, which are stored in a knowledge database within

the machine control. Materials currently available are 1.2344 and 1.2367 hot-working steels, 1.4404 stainless steel, copper, bronze, titanium and aluminum.

Filler material Components produced can be up to 550 mm in diameter, 460 mm deep and weigh up to 600 kg. Almost any internal geometry is possible, as there is an option to use a water-soluble filler material to create internal features, such as conformal

0026-0657/http://dx.doi.org/10.1016/j.mprp.2015.03.013

1 Please cite this article in press as: Met. Powder Rep. (2015), http://dx.doi.org/10.1016/j.mprp.2015.03.013

MPRP-154; No of Pages 2 ADDITIVE MANUFACTURING

ADDITIVE MANUFACTURING

cooling channels in plastic injection molds, that would be impossible to machine conventionally. The filler is subsequently dissolved to leave the desired void. Although traditional additive manufacturing can achieve a similar result, Hermle’s MPA method goes a step further with its

Metal Powder Report  Volume 00, Number 00  March 2015

ability to micro-forge dissimilar materials, enabling mixed metal solutions like a heatconducting copper core inside a tool steel exterior. For writing programs that alternate material deposition and cutting cycles, Hermle has developed MPA-Studio CAM software.

2 Please cite this article in press as: Met. Powder Rep. (2015), http://dx.doi.org/10.1016/j.mprp.2015.03.013

It enables layer-by-layer analysis and machining to build the component geometry. Simulation of the sequence and quality assurance functions for checking the finished components are included. In this way, highly reproducible, top quality parts can be produced in small or large batches.