MoldMaking Technology

DEC 2018

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TIP 46 MoldMaking Technology —— DECEMBER 2018 How to Hard-Mill Effectively CUTTING TOOLS By Jay Ball Hard milling requires the utmost attention to detail to achieve maximum performance and tool life and tight tolerances down to 0.0001 inch. These tips help machinists get the most from hard milling. Maintain a constant chip load and feed rate. Machine tools rapidly fluctuate feed rates when machining complex surfaces and cut- ter paths, which drastically reduces tool life. Machinists must understand that when machining complex surfaces, machine tools do not reduce rpm in conjunction with feed-rate reductions. So, if the machine cannot main- tain programmed feed rates 80 percent of the time, operators should record the average feed rates and then reduce the feed rates and rpm accordingly. For example, if an operator pro- grams a 30,000 rpm and a 150-ipm feed rate, but the machine can only maintain an aver- age feed rate of 75 ipm, the operator should reduce the rpm to 15,000. The subsequent reduction in rpm will increase tool life by 50 percent and impact cycle time negligibly. Do not leave extra stock for finishing. When machinists are machining tool steels above 48 HRC, extra finish stock will reduce output and wreak havoc on surface finish and tool life. A general rule for finish-stock allowance is 1 to 2 percent of the finish-cutter diameter. Most cutting-tool manufacturers base their finishing cutting data on 1 to 2 percent of the tooling diameter engagement, so leaving more than that decreases pro- ductivity. For example, when using a tool with a 0.5-inch diam- eter, leave no more than 0.005 to 0.010 inch of finish stock. Leave consistent stock on all surfaces. After a machinist roughs a complex surface, he or she should run a rest-rough and semi-finish tool path to ensure consistent finish stock on all surfaces. For example, when a machinist roughs out a complex 3D surface using a 12-millimeter ball-nose end mill, and the intended finishing cutter diameter is 8 millimeters, a safe prac- tice for ensuring 0.003 to 0.006 inch of stock on all surfaces is to rest-rough with a 10-millimeter ball-nose end mill and then semi-finish with an 8-millimeter ball-nose end mill. Then the machinist should finish mill with a new 8-millimeter ball-nose end mill to ensure all surfaces have a consistent surface finish. This practice also extends finishing cutter life and enables the machinist to use the finishing ball-nose end mill as a semi-fin- ishing tool when the life of the finishing tool ends. Use strong, precise toolholders. High-precision holders are cru- cial when hard milling to achieve maximum tool life. Run-out must be limited to less than 0.0004-inch to maximize tool life. Machinists can achieve this level of precision with most shrink- fit holders, milling chucks, high-precision collet chucks and select end-mill holders. A precise holder ensures process accu- racy, whereas a less secure holder can cause unpredictable tool life and produce out-of-tolerance surfaces. Follow recommended cutting parameters. Cutting data is opti- mized according to the tool's design and for specific material groups, as some common hardened tool steels present unique challenges, so machinists should use recommendations as a starting point. The machinist can make modifications depend- ing on the application. Image courtesy of Seco Tools. Hard milling is a highly effective strategy for machining complex features on 2D and 3D parts, such as mold cavities, gates, heat-sinks and even die pockets in tool steel above 48 HRC. However, the devil is in the details. CONTRIBUTOR Jay Ball is the product manager for solid end mills for Seco Tools. FOR MORE INFORMATION Seco Tools / 800-832-8326 / jl.ball@secotools.com / secotools.com

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