When ANCA decided to create the ANCA EDG (Electro Discharge Grinding) machine in 2011, the mission was clear. The company wanted to create a high-performance Rotary Electro Discharge Machining (EDM) platform that was able to produce quality tool geometries and fast cycle times.
It was the brainchild of Pat Boland, ANCA Founder and Managing Director: "The erosion process is simple in its complexity. The basis of the process uses positive and negative electrodes with electrolyte to create sparks along a material. ANCA has a 45-year history in making the world's best carbide and HSS tools and we wanted to use that skill set in PCD tooling," he said.
The ANCA EDG machines needed to be simple enough for all types of brazed shear-fluted tools, but complex enough to enable the creation of the infinite variety of helical solid-tipped, veined and chevron tools. Boland added: "We realized early on that with the complexity of tool geometries we wanted to allow our customers to create, the 5-axis interpolation while maintaining the precise erosion gap distance was going to be a challenge."
Maintain the Optimum Spark Erosion Gap with IAC
The ANCA EDG is able to maintain the optimum spark erosion gap for both simple 2D and complex 3D path interpolations, which is fundamental to the process working with high efficacy. This is very simple for 2D paths, however, when 3D path interpolation involves 4 or 5 axes moving simultaneously; surface area, volume and path variation become a challenge. From testing, we knew that the standard was to set the machine feedrate to the lowest allowable to maintain a useable spark gap distance; however, this leads to a lot of air-time and lowers efficiency. To allow the feedrate to remain high and maintain the optimum spark erosion gap, the idea of Intelligent Adaptative Control (IAC) was born.
IAC is an in-time, servo-controlled feature that automatically monitors and controls the erosion gap distance, in-process. Utilizing the EtherCAT functionality of the ANCA Motion AMD5x control system, IAC synchronizes the machine moves with the generator performance. IAC adjusts and maintains the optimum spark gap which is vital while eroding 3D geometries such as PCD flutes and gashes on drills and endmills. With geometry changing in up to 5 axes at once, IAC automatically adjusts the gap distance and machine feedrate to optimize the erosion speed and surface finish. This involves not only speeding up feedrates when erosion is along linear paths but also slowing down feedrates when path changes occur.
Twists and turns along the erosion path lead to scenarios where the electrode wheel is likely to come into close contact with the tool, or comes off the tool. This can lead to optimal, bad and missed sparks along the trajectory. IAC automatically accounts for this and maintains the fastest possible feedrate along the length of any changeable path. This results in increased feedrates, minimum thermal damage, enhanced surface finish, increased MRR and decreased cycle time.
An added benefit of IAC is the ease in which PCD and carbide micro-tools can be manufactured. Since IAC maintains the optimal distance, the chance of wheel collisions and hence tool breakage is low, which is critical when eroding tools under 0.5 mm.
Optimize the Erosion Process with ASC
The current, voltage, duration, time-off and therefore intensity of sparks change based on the material that is being eroded. That is, PCD will require certain parameters as opposed to carbide (HM) and high-speed steel (HSS). The challenge is that PCD wafers are generally 0.6 mm PCD with a 1 mm carbide backing-sintered PCD, chevron tools and solid-tipped tools are formed onto carbide backing also. When aggressively eroding along the PCD-carbide border, erosion parameters optimized for PCD can inadvertently over-erode the carbide backing. This in turn leads to over-erosion at the PCD-carbide border, named an "undercut" as it selectively erodes the carbide under the PCD. Additionally, it can lead to "cobalt leeching" which is when the PCD binder, cobalt, is preferentially eroded away.
This is akin to digging under the foundations of a paved pathway. If you dig too much material away from under the path, eventually the path will collapse. Machine testing showed that the undercut and cobalt leeching during heavy roughing lead to a brittle border along the cutting edge and premature tooling wear. To avoid this happening and to optimize the erosion process, Adaptive Spark Control (ASC) was created.
Simple and Complex PCD Tooling
ASC uses the Digital Signal Processors (DSP) and Field Programmable Gate Arrays (FPGA) on the generator itself. The EDG erosion generator is able to monitor and process every spark, in real time. The waveform of each spark is automatically monitored and categorized based on material being eroded, erosion gap distance and other factors essential to optimal erosion process. The generator can then dynamically adapt the energy level of each spark (current, voltage, duration and time-off) to suit the material being eroded.
ASC optimizes the erosion process leading to less cobalt leaching and a reduction in undercut at the PCD-carbide border. This leads to a stronger cutting edge and a finished tool that is less prone to chipping. This helps achieve longer tool life, less tool wear and lower tooling costs. Testing on tooling suited to the machining of carbon fiber reinforced plastic (CFRP) showed a tool life increase of up to 100%.
Boost the Power of Electronics
ANCA leaned on the expertise from its sister company, ANCA Motion, to optimize the electronics to enable higher and more aggressive erosion while maintaining high surface finish results. When compared to equivalent componentry, the "mega-amp per pulse" technology enables ANCA customers to broaden the power range they can access and utilize. The ANCA Motion SparX Erosion Generator exhibits enhanced performance over the range of extra-heavy roughing to ultra-fine finishing operations, utilizing Pico-pulse technology for high energy-density ablation. This enables increased controllability, providing customers with optimized feedrates, better surface quality and reduced cycle times. This pulse precision allows erosion that ranges from ultra-low energy pulses for exceptional ultra-fine finishing through to high energy pulses for fast material removal.
In the PCD erosion process, cycle time is directly related to the material removal rate (MRR). The ANCA Motion SparX Erosion Generator delivers increases in MRR utilizing the new Extra-Heavy Roughing, Super Fine Finishing and Ultra-Fine Finishing operations. What this equates to is an increase in MRR and a 50% decrease in cycle time compared to competitor machines. Additionally, erosion surface quality also sees an improvement across all power modes. Polished surface finishes of Ra < 0.1µm and Rz < 0.5 µm can be achieved using the newly release Ultra-Fine Finishing process with Pico-pulse technology. These operations enable the production of enhanced cutting edges necessary for demanding cutting tool applications.
"ANCA focuses on what our customers want to achieve with their erosion process. They told us that they wanted a process optimized for helical and round PCD tooling. We worked closely with ANCA Motion to design our erosion generator to suit not only shear tooling but the infinite array of highly complex geometries, rather than re-using generator technology originally created for wire EDM. Our approach turned the industry on its head. We let the geometries dictate the process, not the process dictate the geometries available," said a company spokesperson.
Authored by Tom Nathan, ANCA PCD Erosion Product Manager
For more information contact:
ANCA Inc.
31129 Century Drive
Wixom, MI 48393
248-926-4466
usainfo@anca.com
www.anca.com