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 There are many components to an effective high speed machining process for mold and die makers. Much has been written about the impact HSM has had on CNC machine tools, spindles, toolholders, cutting tools, and controls. Often forgotten is high speed machining’s impact on tool path programming techniques.

CAD/CAM technology is evolving today to meet the specific needs for new tool path strategies to suit the HSM environment. Here, HSM can be defined as the use of higher spindle speeds and feed rates to remove material faster without a degradation of part quality. The goal is to finish mill molds and dies to net shape, to improve surface finish and geometric accuracy so that polishing can be reduced or eliminated.

To facilitate high speed machining, a CAM system should:


The challenge to the CAD/CAM system is to make passes with very small stepovers at very high feed rates. And this must be accomplished without CCGT Insert forcing the tool to make sharp turns, because the look-ahead features of HSM controls will automatically reduce the feed rate when they detect a corner approaching. In addition, in order to overcome data starvation—which will also impair the feed rate—the CAD/CAM system may be required to output tool paths appropriate to HSM controls capable of running NURBS-based G-code.

This article discusses CAD/CAM features that can help die/mold shops realize effective HSM.


“Smart machining” is a feature that aims to produce an intelligent, optimized tool path. Its functionality can include options for examining data between Z layers—including HSM feed connections, slope control machining, and geometry identification.
To achieve near net shape when roughing, it is important for the CAM software to understand what changes in surface Tungsten Carbide Inserts topology occur between the layers of down-steps. Knowledge of stock remaining (KSR) algorithms must look ahead to determine where extra down-steps are necessary. Smart machining is how a CAM system machines this “between layers” material. By roughing in this manner, often the semi-finish pass may be eliminated, saving on machine time and tool wear.

Smart machining may also include helical ramping functionality. This is used for pocket machining. The helical ramping function determines helical movement based on entry angle and geometry. This function is most important when the tool reaches a closed area of workpiece. It can make the cut shorter and safer by eliminating air cutting, as a result of tailoring the tool path to the geometry of the enclosed feature.

Lately, many leading-edge CAD/CAM systems have introduced “re-roughing.” The re-roughing idea is at the heart of knowledge-of-stock remaining functionality.

The technique is excellent for shops where different roughing methods are employed. It works like this: Initial rough machining is performed first, then the resulting form is used as the new stock for a subsequent roughing tool path. Roughing can then proceed according to a different method—parallel, spiral, stock-spiral, what have you—with just the new stock. A likely result is a more efficient overall cutting strategy that keeps the tool in the material to reduce air cutting.

Similarly, knowledge of stock remaining allows tool paths to be created in areas where previous tools did not remove all of the material. There are many methods to remove this uncut material, including pencil tracing and rest milling.

The tool path trajectory for these follow-up machining strategies is optimized based on the knowledge of stock remaining from the previous tool path. For example, the tool trajectory is optimized to protect the tool and the holder from gouging based on the remaining stock.
The follow-up functions make the finish machining process more effective. Without pencil tracing, rest milling, and similar re-machining strategies, the finishing tool could be fed into a considerably larger volume of material (where it would probably break) when it reached the corners of enclosed areas. Re-machining relieves these corners.

How to include corners in the overall tool paths is also an important consideration. In order to produce optimized tool paths for HSM, the CAD/CAM system must be able to deal effectively with internal sharp corners in the workpiece. A corner treatment function for HSM rounds the sharp motion out of the tool path. If allowed to remain, this sharp motion would be seen by the controller’s look-ahead function, which would reduce the feed rate accordingly. A CAM system that can generate fluid tool motions during corner machining can maintain more consistent high feed rates.

Side steps are the connections that create effective transitions between adjacent tool paths when feed rates are particularly high. Parallel scan-line surface machining is the type of machining that has been used for the last ten years to finish machine multi-surface models. This type of machining tends to produce sharp stepover moves at the end of every pass. Using simple “looping” tool paths in place of sharper turns between scan passes is an appropriate solution at moderate feed rates (20-40 ipm). However, at higher feeds, these simple rounded moves are still too sharp. An alternative that has proven more effective in some cases is a “golf club” stepover between passes.

The new G-code “G6.2” represents the NURBS spline. This command expands the choices from traditional linear and circular interpolation to interpolation along a spline represented by control points and knot points. By consolidating a complex, curving tool path into a single line of the program, this function saves on NC data, potentially resulting in more fluid high speed machining.

Some CAD/CAM systems—but not all—create the tool path directly in the spline format. The resulting tool path incorporates direct knowledge of the CAD model. This is important because some CAM systems generate NURBS tool paths based instead on the linear tool path, by approximating this linear path in terms of NURBS paths. Because this is a double approximation, tolerance stacking errors may result.

One of the newer techniques to increase rough machining speed involves a tool path strategy called trochoidal machining. This machining style removes material using the side knife-edge of the cutting tool.

“ Trochoid” describes a type of curve. A trochoid is the trace of a point fixed on a circle that rolls along a line. More generally, a trochoid is any curve that is the locus of a point fixed to a curve A, while A rolls on another curve B without slipping. (See illustration, below.)

Trochoidal machining is well suited to HSM because the cutting tool always moves along a curve of constant radius. This allows a consistent feed rate to be maintained throughout the machining process.

A style of roughing called plunge roughing uses specially made cutting tools to machine deep molds and dies. Plunge roughing employs a drill-type tool path to remove material from deep within the cavity in the Z direction of the machining center. The result has proven to be an efficient method of roughing deep-cavity geometry.
Plunge roughing is drawing attention in machining large molds and dies. An extended protrusion in the tool is required for machining these workpieces. In typical milling, this extended protrusion would lead to vibration. But in this Z-directed machining, vibration is reduced, opening the door to more efficient roughing in many processes.

 
Plunge-roughing tool paths resemble drilling moves. This technique is particularly effective at roughing out deep cavities.
The Next Step

The use of HSM strategies normally requires the material to be removed with very shallow cuts and with small stepover. The smoothness of the machined surface is determined in large part by the height of the scallop between adjacent passes . . . and by taking a smaller and smarter stepover, the scallop height goes down. Thus, lighter depth of cuts contribute to reduced hand polishing. At the same time, HSM offers an efficient way to use very small tools. This can make it practical for high-speed CNC machines to generate fine details that might otherwise require inserts or EDM. Reducing or eliminating EDM can lead to substantial time-savings—not only because EDM is a slow process, but also because it requires the additional step of producing the electrode.

In other words, high speed machining lets the machining center do more. That’s why the complement to high speed machining, in the minds of many CAD/CAM developers, is a system that can automate much of a machining center’s programming.

The ultimate aim is to have a CAM system that can recognize features and automatically machine the workpiece using the shop’s best practices. The next generation of CAD/CAM systems will marry both manufacturing feature recognition and knowledge-based machining strategies to automate the complete mold machining process. The resulting system will provide complete automation “out of the box,” and yet still allow experienced toolmakers to tailor the system to match their shop practices. When will this system arrive? As an industry, we’ll get there one small step—or stepover—at a time.

About the author: Dan Marinac is strategic marketing manager for Cimatron Ltd. (Livonia, Michigan).


The Carbide Inserts Blog: https://carbiderods.blog.ss-blog.jp/

“Walnuts are cool,” Shawn Wentzel says with a shrug when asked why he decided to plant 7,000 walnut trees on his property in Lodi, California. Now two years old, the CCMT Insert orchard is a growing side business. Surrounded by rolling plains and vineyards, it begins at the back door of his primary source of income: an old horse-barn-turned-machine-shop with plenty of space for additional milling and turning equipment to complement the current stable of six machine tools.

He named the shop Wenteq, and with revenue growing at approximately 10 percent per year, prospects for filling the rest of the 15,000-square-foot space seem bright. The newest technology addition is a robot to load and unload various parts for automotive and agricultural equipment from a turning center. With Mr. Wentzel opting to do much of the legwork, integrating the robot is a work in progress. No matter. As was the case with the walnut trees, he sees no barrier in his lack of automation-integration experience. “There&TCGT Insert rsquo;s nothing like doing it yourself,” the 36-year-old says, articulating the independent spirit that first led him to turn his machining hobby into a business nearly 15 years ago. “What can anyone learn in school that they can’t learn on the shop floor?”

This inclination to make his own way is one reason why Mr. Wentzel says he appreciates the open-architecture Thinc-OSP CNCs on the shop’s five Okuma machine tools. These controls’ application programming interface (API), which is essentially the set of tools and resources ?used to integrate with? the CNC and develop functionality for it, is based on the same Microsoft Windows operating platform that drives many personal computers. That means the CNCs can use much of the same software as any other Windows-based computer, including downloadable apps such as the GPS navigators, heart-rate monitors and weather trackers common to consumer mobile devices.

Of course, the apps Okuma offers are designed to make life easier in a CNC machine shop. Many are available for free via the machine tool builder’s online app store. This store has been growing steadily since its launch in 2014, thanks in part to the active participation of shops like Wenteq. Whenever Mr. Wentzel has had an idea—whenever there is something he wished his CNC could do—he says he likely can make it happen by asking Okuma distributor Gosiger Automation to develop an app.

He is not alone. According to Okuma, many apps now available for download originated with end users like Mr. Wentzel. In this way, the company essentially invites its customers to participate in the development of new CNC functionality. Mr. Wentzel was an early enthusiast of this approach, and Wenteq became an early proving ground after the app store’s debut. “When an app came out, we were never scared to throw it on a machine and try it out,” he says.

These small programs all help Mr. Wentzel and his three shopfloor employees avoid making mistakes or wasting time, he says. For instance, the shop does not have an offline tool presetter (not yet, anyway), so many of the most commonly used apps help streamline the manual entry of compensating offsets at machine controls. Others provide basic machine monitoring functionality. Here are five examples of apps the shop finds valuable, two of which were created at Mr. Wentzel’s request:

This app enables inexperienced operators to edit common variables in the control’s parameters section without making mistakes. (Common variables are used to store offsets, part counts and other temporary data that is specific to a particular part program.) “I don’t want employees going into the CNC’s parameters section,” Mr. Wentzel explains. “The common variable section is one page away from a machine system location. If something were to be changed on this page, the machine could crash.”

Instead, Variable Manager presents only the relevant common variables, which can be pulled from the CAM program or defined by Mr. Wentzel when he programs a job. All variable slots can be clearly labeled for convenience and efficiency, and a “revert” function can quickly restore previous values in the event of an error.

On the shop’s palletized horizontal machining center (HMC), Variable Manager makes it easy for even inexperienced operators to change tools for a new job without interrupting production. To facilitate this, the machine’s cycle includes a “dummy pallet” associated with a CAM program that does nothing more than initiate a macro to touch-probe the newly changed tools. Any time before this pallet cycles in, the operator simply opens Variable Manager, inputs the new tool numbers and clicks “set” to initiate a probing cycle for every changed tool. In short, tools can be probed whenever it is convenient rather than immediately upon inserting them in the 146-position automatic toolchanger (ATC). “It puts only what’s relevant in front of you,” Mr. Wentzel says about Variable Manager. “You just type in the tool numbers and click once.” (Tool numbers generally correspond to the number of the slot in the ATC—that is, tool 1 goes into slot 1).

Variable Manager also enables adjusting a machine’s schedule on-the-fly by simply changing the variable associated with part count. Capability to change part counts from the floor, while the machine runs and without editing the program, is particularly useful for the shop’s bar-fed turning centers, Mr. Wentzel says. As is the case with HMC tool offsets, there is no need to navigate through the CNC to find the variable associated with part count. There is little risk of changing the wrong variable or altering a parameter that should not be changed.

Developed by Gosiger at Mr. Wentzel’s request, Manual Data Input (MDI) Tool Call is used for the shop’s LB-3000 lathe. With a subspindle and a Y-axis turret that accommodates as many as 96 tools for both front- and backworking operations, setting offsets on this machine can be complicated. Adding to the confusion is the fact that as many as eight tools can be stacked in the same turret station (four for the main spindle and four for the subspindle). Each requires its own offset, but tools stacked in this way are more difficult to probe because they do not line up with the centerline of the spindle at the turret’s home position. Jogging the turret into position along the Y axis requires either moving it manually (and carefully) or entering a series of coordinate moves into the CNC (again, carefully).

MDI Tool Call reduces this task to just a few keystrokes. The operator simply opens the app, enters the tool-station number, designates which tool requires a new offset, and presses “start” to move the Y axis into the correct position. “I was typing in the same stuff over and over again, and I thought ‘This is dumb,’” Mr. Wentzel recalls about the app’s development. “I approached Gosiger with an idea to make it easy for anyone to do it fast, and without any experience or knowledge.” 

Wenteq’s work sometimes demands changing tool offsets frequently, sometimes between every part. “We had a tight-tolerance project a few months ago in which we were measuring every part to check for insert wear and then changing offsets as needed,” Mr. Wentzel says. “Fat-finger it one time in a situation like that, and you can lose a part.”

There is little risk of that as of just a few months prior to Modern Machine Shop’s visit late last year, when Mr. Wentzel pitched Gosiger on the functionality that became the Easy Adjust app. This app presents operators with a simple interface consisting of four slider bars, each corresponding to the offset for a specific cutting tool. Clicking the “plus” and “minus” buttons adjusts the offset by a prespecified amount (changing this amount requires a password). As the operator adjusts the buttons, the bar changes color depending on how close the adjustment gets to prespecified minimum and maximum limits. Limiting the display to four offsets helps keep things simple, he adds, noting that few jobs require adjusting more than that. This simplicity enables even the least-experienced shopfloor employees to be productive while they learn, and above all, to avoid mistakes and scrapping parts.

Around the time the Okuma app store debuted in 2014, Mr. Wentzel had been seeking a simple, affordable solution for basic machine monitoring. “For one system I considered, the company wanted thousands of dollars plus a monthly fee,” he recalls, “but we don’t need all that functionality. We’re small enough that we don’t need deep utilization information or fancy dashboards with a bunch of lines. We were just looking for a simple, at-a-glance view of machine status.”

As it turned out, this functionality was available for free at the Okuma app store. Since then, basic status information for every machine tool has been displayed on two 50-inch TV monitors that are visible throughout the shop. Green indicates a machine that is running, orange indicates idle equipment and red denotes a potential problem.

Mr. Wentzel says setup was easy, with the free apps pushing status information through the same Wi-Fi connection used to link machines and send part programs. An Intel Compute Stick—essentially, a mini Windows 10 computer that plugs into a USB port—installed in each of the monitors receives the data from the machines. Mr. Wentzel can also view the data on his smartphone.

This is all possible thanks to MTConnect, an open-source communications protocol that facilitates interconnection and communication among CNC machine tools and other manufacturing equipment. Specifically, Wenteq uses three apps: MTConnect Agent/Adapter, which provides the basic MTConnect communications functionality; MTConnect Display, which scans a shop network for compatible devices (in this case, the Compute Stick) to make installation plug-and-play; and MTConnect Display Mobile, which provides the mobile phone connection. 

Access to status displays is not Mr. Wentzel’s only means of monitoring machine tools. While walking the floor of the 2018 International Manufacturing Technology Show (IMTS), he received a call with a distinct ringtone, one assigned to a specific entry in his contact list. On the other end was not a person, but one of his machines, reporting a problem. This simple capability is thanks to the free Machine Alert app, which sends CNC status information and screen shots via email or text whenever certain user-specified conditions are met.

Back in 2014, Mr. Wentzel had to download every app. Now, many come pre-installed on the CNCs of new Okuma machines, including MTConnect Agent/Adapter, apps that track maintenance schedules, and apps that calculate overall run time and remaining run time, among other capabilities.


The Carbide Inserts Blog: https://cncinserts.blog.ss-blog.jp/

Supply chain issues are driving more companies to bring manufacturing back in-house. Parallel to this trend in the automotive industry is the rise of electric vehicles and increasing automation. Nidec Machine Tool, responding to the needs of the industry, is debuting its GE15HS gear hobbing machine. With emphasis on high speed, precision and efficiency, Nidec designed the machine to produce gears for electric and hybrid cars and serve in robotic and automation applications.

The GE15HS model is designed LNMU Insert for gears with a maximum diameter of 150 mm, a size widely used in automobiles and motorcycles. The high-speed, high-torque direct-drive motor for the main cutting spindle provides a maximum spindle speed of 6,000 rpm —  three times faster than previous models. The direct-drive mechanism motor uses the torque coming from a motor without passing through a gear box or other mechanism in order to control driving loss due to friction and reduce wear on parts. The high-efficiency spindle holding the workpiece uses a special table. This table, in turn, provides rigidity and high-speed rotation to handle the necessary thrust load for high-efficiency machining.

Used in combination with Nidec Machine Tool’s new materials and coatings for cutting tools, the GE15HS model provides stable mass production with a maximum cutting speed of 1,500 meters per minute. According to an in-house test result, cutting gears with Nidec’s super-hard cutting tools yields a surface roughness Cutting Carbide Inserts of less than Ra 0.4 — on par with gear grinding.

The goal of the GE15HS is to provide process efficiency. By eliminating the finishing process of shaving prior to heat treatment, Nidec says the GE15HS can improve productivity and reduces processing cost.


The Carbide Inserts Blog: http://leandercle.blogtez.com/

Carbide threading inserts have become a common tool used in the production of threaded components. These inserts are used in a variety of industries, such as automotive, aerospace, and medical, to produce accurate, threaded parts and components. Not only are they cost-effective and efficient, but these inserts offer a number of advantages that make them a preferred choice for a wide range of applications.

The most important advantage of using a carbide threading insert is its strength. Carbide is one of the hardest materials available and can withstand high temperatures and pressures, making it ideal for machining components with tight tolerances. Additionally, carbide inserts are extremely wear resistant, so they can be used for a long time without having to be replaced.

Another advantage of carbide threading inserts is their dimensional accuracy. Because of their high precision, these inserts can be used to create components with very tight tolerances. This means that parts produced using carbide inserts are more likely to meet exacting specifications and stay within tolerances.

Finally, carbide threading inserts are extremely efficient, which makes them a great choice for applications that require high productivity. The inserts are designed to reduce the number of passes required to complete a job, as well as reduce the number of cutting edges needed to create a thread. This makes them a time- and cost-effective solution for creating high-quality threaded parts.

Overall, carbide threading inserts offer a number of advantages that make them a preferred choice for many applications. Their strength, dimensional accuracy, and efficiency make them a great option for producing precise, reliable components quickly and cost-effectively.

Carbide threading inserts have become a common tool used in the production of threaded components. These inserts are used in a variety of industries, such as automotive, aerospace, and medical, to produce accurate, threaded parts and components. Not only are they cost-effective and efficient, but these inserts offer a number of advantages that make them a preferred choice for a wide range of applications.

The most important advantage of using a carbide threading insert is its strength. Carbide is one of the hardest materials available and can withstand high temperatures and pressures, making it ideal for machining components with tight tolerances. Additionally, carbide inserts are extremely wear resistant, so they can be used for a long time without having to be replaced.

Another advantage of carbide threading inserts is their dimensional accuracy. Because of their high precision, these inserts can be used to create components with very tight tolerances. This means that parts produced using carbide Cutting Inserts inserts are more likely to meet exacting specifications and stay within tolerances.

Finally, carbide threading inserts are extremely efficient, which makes them a great choice for applications that require high productivity. The inserts are designed to reduce the number of SCGT Inserts passes required to complete a job, as well as reduce the number of cutting edges needed to create a thread. This makes them a time- and cost-effective solution for creating high-quality threaded parts.

Overall, carbide threading inserts offer a number of advantages that make them a preferred choice for many applications. Their strength, dimensional accuracy, and efficiency make them a great option for producing precise, reliable components quickly and cost-effectively.


The Carbide Inserts Blog: https://hugoamos.exblog.jp/

Emag hosted an open house along with the launch of its new Laser Welding Laboratory June 8 at its U.S. headquarters in Farmington Hills, Michigan. The event was an opportunity for the company’s customers, representatives and distributors to witness live equipment demonstrations along with technical presentations made by Emag executives and members of other industry groups.

The centerpiece of the new lab is the ELC 250 Duo compact laser welding system for machining gear components. This twin-spindle, two-station machine allows for loading and unloading the spindles during the cycle. Primarily targeting the automotive industry, the lab will provide services including weld-seam-design consultation, pre-turning and weld-prototype support, among others.

In addition to the ELC 250 Duo, live demonstrations were conducted on the VL 2 and VL 4 vertical modular turning machines, offering high production performance and featuring integrated Cutting Inserts automation and space-saving vertical lathes. Demos were also performed on the VT 2-4 and VT 4-4 machines for shaft production with high-speed loading and unloading processes.

Peter Loetzner, CEO of Emag LLC, made opening remarks, followed by Andreas Mootz, managing director of Emag Automation, Jens Standfuss, with Fraunhofer, and Achim Feinauer, COO of the Emag Group.

Pat McGibbon—vice president of strategic analytics at AMT–The Association For Manufacturing Technology—spoke on “The Manufacturing Economy 2016 and Beyond.” He listed the primary challenges to the U.S. manufacturing technology market as taxes and slowdowns in the automotive and energy sectors. As for the path of trends in manufacturing technology, he cited Oxford Economics, which expects "a decline of 1.2 Shoulder Milling Inserts percentage points but a big finish to the year," ITR Economics, which sees a “rise in demand coming—be ready,” and Steven Kline, director of market intelligence at Gardner Business Media, who says “the downturn in manufacturing technology orders is average—both in duration and depth.”

 
The Carbide Inserts Blog: https://reedelsa.exblog.jp/

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