Cutting Tools Pages 51 to 60 Three Ways to Accurately Machine Hardened Mold Materials By Christian Hämmerle Most molds are made from hardened or heat-treated tool steel or hardened metals, and are challenging to produce, especially as their complexity increases. Strong forces also impact the cutting tools that machine the cores and cavities and make the channels and supply systems for coolant or hydraulic fluid. These aspects of moldmaking make process reliability a chal-lenge. A good example is tool breakage during deep-hole drill-ing or increased tool wear due to material hardness and tough-ness — both negatively impact the inal part’s dimensional accuracy and surface quality. Making the right cutting tool choice to meet the complex requirements and conditions involved in mold machining is a challenge, especially for many small-and medium-sized shops that often lack the time and workforce to develop optimal machining strategies. Design Considerations Here are three cutting tool design consider-ations for improving your process reliability and cost eficiency when deep-hole drilling, pro-ducing internal threads or machining highly brittle mold materials. . When deep-hole drilling, use a pilot drill with land design that places the carbide mass directly behind the cutting corner or in the area where the most signiicant cutting force and highest temperature occur. Also, use a deep-hole drill up to x DC. The radially located lands dissipate the increased temperature created by the cutting operation into the chip. This unique positioning of the guiding chamfers results in excellent straightness of the holes produced with a reduced tendency to vibrate. The result is drilled holes with very high dimensional accuracy and surface quality. This strategy and design increases the drill’s stability in the precise area, ensuring productivity and reliability, even in the case of inclined exits or cross holes when particularly high mechanical loads are placed on the drill. . Consider the drill’s substrate and coating as they are essential to high heat resistance. For example, carbide accom-This unique positioning of the guiding chamfers results in excellent straightness of the holes produced with a reduced tendency to vibrate. The result is drilled holes with very high dimensional accuracy and surface quality. A washing machine back panel mold highlights how the right cutting tool can improve cost effi ciency when machining highly brittle mold materials. modates higher temperatures than conventional drills, while a TiAIN/AICrN coating (grade WJEJ) increases the hot hard-ness of the drill even more. . When drilling the ittings that connect coolant chan-nels to a mold made of hardened material, use an orbital drill thread milling cutter to machine the core hole and thread and chamfer, if necessary, in a single operation. The milling geometry on the face produces stabilizing forces in the axial direction, improving stability when milling and decreasing deflection. This solution reduces the need for radius corrections and slows down tool wear signiicantly. Also, a -degree helix angle and internal coolant offer reliable chip evacuation, enabling a mold builder to machine even tougher steels and deeper threads reliably. FOR MORE INFORMATION FOR MORE INFORMATION Walter Tools christian.haemmerle@walter-tools.com / walter-tools.com info Christian Hämmerle, Component Manager, Mold & Die info 60 MoldMaking Technology — — JULY 2023 Image courtesy of Walter AG.