As a supplier of metal-removal tooling for more than 100 years, Ingersoll Cutting Tool Company (Rockford, Illinois) has sought to help manufacturers remain competitive by providing innovative and productive metal-removal solutions. Cutting Carbide Inserts Since the early 1990s, the company has used Vericut software from CGTech (Irvine, California) as a component of its manufacturing process.

“We have had Vericut in production for so long, I think that it is taken for granted,” says Paul Gerardy, systems engineer. “With our shop primarily running five-axis programs, machine crashes were a factor in our decision to implement the software. It keeps the spindles in the shop turning. Now, we rarely have crashes, and we no longer provide setup pieces for NC program prove-out.”

The NC programmers at Ingersoll also rely on the simulation software to prevent mistakes when programming complex, five-axis parts. The verification software that simulates from post-processed code allows the user to detect errors before they happen on the shop floor. Many CAD/CAM systems output program data as an APT/CL translator program or in ASCII neutral format. This data defines the principal tool path, speeds and feed rates as a machine tool-independent generic NC program. The post-processor receives this file and converts it to the specific machine tool instructions required to control the axis motion, tool changes, cutter compensation, coolant pumps and more. Unless discovered by the independent verification software, errors that are introduced at this stage will go undetected until a machine crash occurs or during a manual prove-out run, the company says.

Vericut can prove-out the machine and post-processor before they arrive in the shop. “We try to have the programming process for a new machine setup before the machine tool hits the floor,” Mr. Gerardy says.

The capability to simulate NC programs from post-processed code became critical when the company was forced to change CAM systems from a mainframe-based APT system to Pro/NC. The time frame for the transition was tight, because the company had just 3 months before it would lose access to the mainframe. Because the software was independent from the CAM system or post-processor, it facilitated a smooth transition.

“It was like Y2K all over again, except we knew exactly what we were up against,” says Mr. Gerardy. “Not only did we lose our CAM system, but we also lost all of our post-processors. After that, we purchased ICAM to post-process Pro/NC CL data. It was nice to have at least one component of the NC programming process that we could count on. You could say that the software was a firewall between the office and the shop, and it smoothed out the transition to Pro/NC.”

The software is a key part of the company’s tool assembly building routine. Ingersoll does not use pre-defined tool assemblies, but rather, it relies on the software to determine the minimum extension length for each tool assembly. That information, along with minimum and maximum gage-length information that is output from the post-processor, enables the company to select the most rigid tool assembly for the job.

“The machine operators are confident about this method because they know the tool assembly we specify will not cause a collision,” says Mr. Gerardy. “As a systems engineer, I like the ease with which I am able to configure the software for automation. We like to automate everything we can for the NC programming group. Vericut allows us to do just that.”

According to the company, the capability to automate the verification process is crucial because the company’s NC programmers create numerous programs per day. So it is imperative that the software is not a cumbersome part of the process.

A small reduction in machining time can translate to substantial savings over the course of a single production run, the company adds. Mr. Gerardy and System Engineer Pete Risley implemented the NC program optimization software into their manufacturing processes. As a result, every NC program sent to the shop is first optimized using the OptiPath module. Consequently, a few extra minutes spent early in the programming stage can save time at the machine.

OptiPath works by analyzing either the post-processed NC program (G-codes) or the direct CAM system output. It then divides the tool motion into smaller segments determined by user-defined settings in the software. By analyzing the amount of material removed in each segment, the software assigns the ideal feed rate for each cutting condition encountered, says the manufacturer. It then outputs a new NC program, which is identical to the original one but features improved feed rate settings. The software does not alter the toolpath trajectory.

“When we first implemented the module, our operators were skeptical,” says Mr. Gerardy. “However, it wasn’t long before the operators were calling the NC programmers and telling them when they forgot to optimize the tape. Our NC programming group pumps out a lot of programs every year. We have implemented OptiPath in such a way that it only adds a few minutes to their programming process, if anything.”

Even though the optimization process may seem like an extra step, it can simplify programming.

“With OptiPath, the programmers do not have to be quite as picky about inefficient portions of the tool Shoulder Milling Inserts path because the module will take care of it,” Mr. Gerardy says.

In addition to more efficient feed rates, optimized NC programs typically result in parts with better surface finishes, the manufacturer says. Additionally, the optimized programs are said to produce constant chip load. Therefore, tools may last longer, and machines can run smoother.

“It seems like the more complicated jobs are the ones that we really see big savings,” Mr. Gerardy adds. “When we first implemented OptiPath, we had the NC programmers record time savings for every job that they processed for about a year.”

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005929477719.html

Mapal’s HighTorque Chuck (HTC) with narrow contour combines the benefits of hydraulic expansion with 3-degree back taper. This feature is accomplished via additive manufacturing, which enables the clamping range to be positioned very close to the chuck tip for an optimum radial runout of less than 3 microns at the location bore and less than 5 microns at 2.5×D as well as high shape accuracy and good vibration damping. Machining Carbide Inserts The damping in the system reduces microstructure cracking at the cutting edge, which in turn ensures longer tool life and less strain on the machine spindle. Furthermore, Mapal explains, the additive process eliminates the need for the soldered joint that has been a limiting factor until now. This chuck shares the benefits of the standard HTC, including thermal stability. Operating temperature ranges to 338°F (170°C), promoting additional process reliability.

With benefits for moldmaking as well as automotive and aerospace applications, this chuck is designed for all machining operations in contour-critical areas.

The chuck is available in clamping diameters of 6, 8, 10 and 12 mm for HSK-A63 and SK-40 interfaces. Intermediate sleeves enable additional diameter ranges to be covered. In addition, the chuck is Thread Cutting Insert optionally available with a dynamically-balanced HSK connection.

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005979934200.html

Trumpf offers its TruLaser 5030 fiber laser machine with an 8-kW TruDisk laser. According to the company, the machine can process thin materials at high speed as well as thick material with high quality. The X, Y and Z axes measure 3,000 × 1,500 × 115 mm, respectively. A stable machine concept enables precise contour cutting. With the company’s BrightLine fiber, the machine can process steel as thick as 1", and stainless steel and aluminum as thick as 1.5".

Features contributing to productivity include mobile machine operation and monitoring with the MobileControl app; a Drop&Cut function for fast and efficient post-production; and efficient use of remainder CCMT Insert sheets. The laser source, machine, optics, optional cutting technologies, VBMT Insert automation, storage systems and software are all developed by Trumpf to work in tandem for maximum performance and low cost-per-part.

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005979895118.html

CNC Engineering Inc. will now play a key role in the distribution, integration and support of the Meltio metal 3D additive manufacturing (AM) solutions for FANUC CNC and robotic systems in the U.S. market.

According to CNC Engineering Inc., it specializes in the integration and support of FANUC CNC machine tool retrofits, Renishaw probe and laser systems, rotary tables and additional axes, FANUC Robots and now Meltio solutions.

Meltio Carbide Milling Insert is said to take metal AM to the next level by developing high-performance, affordable and easy-to-use metal AM solutions using wire laser metal deposition (LMD) technology, which the company says is the safest, cleanest and most affordable metal feedstock in the market.

CNC Engineering and Meltio say they have collaborated to design a solution that combines the power and reliability of FANUC CNC with cutting edge AM technology. This hybrid additive and subtractive manufacturing solution is said to have several advantages, Cemented Carbide Inserts including offering one of the most affordable hybrid manufacturing solutions. It is also said to provide production savings as it offers nearly 100% material utilization. It can also generate complex geometries in a single process and combine different materials into a single part. Users can also utilize AM in their shops by taking advantage of existing machines, thereby saving floor space.

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005901341397.html

There are two critical points when considering quick change tooling systems for machines —  rigidity and accuracy — according to Iscar. The company’s NEO SWISS Modular Quick Change Tooling Line for Swiss-type machines has a robust rotary wedge mechanical design for clamping rigidity.

Due to the processes on Swiss machines and the difficult materials being machined, the depths of cuts can be deep, compounding the need for an extremely rigid system. Accuracy is essential when changing tools for part requirements and achieving seamless change-over from job to job. The repeatability of Iscar’s NEO Swiss tools is ±0.0008” Shoulder Milling Inserts [±0.02mm].

The materials cut in Swiss shops make holders that are coolant-thorough a critical factor in part quality, tool life and chip control, according to Iscar. Because of this, Iscar incorporates coolant-thorough technology when designing its products. NEO Swiss heads have coolant holes strategically placed for efficient coolant introduction. The NEO Swiss was designed so there is no need for a bulky tool head, reducing the possibility of chips getting caught on heads or coolant nozzles. 

A Y-axis option is also available for the ISO Turn NEO Swiss head. Iscar says this component can add rigidity to turning operations by inverting the insert from X-axis to Y-axis orientation changing the cut forces from radial (perpendicular to the shank) to axial (parallel Carbide Grooving Inserts to the shank). This orientation also is also said to improve chip evacuation. By positioning the insert inverted, it is possible to take advantage of gravity to project chips into the conveyor.

The NEO Swiss line comes in 0.500 inch, 12 mm and 16 mm shanks with plans to expand the line more in the future.

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005925320885.html