CHINESE CARBIDE INSERTS,CNC TURNING CHINA,FACTORY IN CHINA

Carbide tools have revolutionized the machining industry with their exceptional hardness, durability, and efficiency. But what is the history behind the development of these cutting-edge tools?

The story of carbide tools can be traced back to the late 19th century when a French chemist named Henri Moissan discovered a new compound called carborundum. Carborundum is a crystalline form of carbon and silicon, which is extremely hard and heat resistant. This discovery laid the foundation for the development of carbide materials.

In the early 20th century, researchers began experimenting with different compositions of carbide materials to create cutting tools that were harder and more durable than traditional steel tools. It wasn't until the 1920s that the first commercial carbide cutting tools were introduced by General Electric. Drilling Carbide Inserts These tools were made from tungsten carbide, which proved to be a game-changer in the machining industry.

During World War II, carbide tools became even more essential as the demand for precision machining increased. The ability of carbide tools to withstand high temperatures and maintain sharp cutting edges made them invaluable for producing weapons, aircraft parts, and other crucial components.

Since then, carbide cutting tools have continued to evolve with the introduction of new coatings and compositions to further enhance their performance and longevity. Today, carbide tools are used in a wide range of machining applications, from cutting and drilling to shaping and finishing, in industries such as automotive, aerospace, and electronics.

In conclusion, the history of carbide tools is a testament to human ingenuity and innovation in the field of materials science. From the discovery of carborundum to the development of modern carbide cutting tools, this journey has paved the way for advancements in precision machining and manufacturing.

# by jackjerome | 2024-09-07 12:39

In recent years, there have been significant innovations in U drill insert technology that have greatly improved the performance and efficiency of machining operations. U drill inserts are widely used in the metalworking industry for drilling and cutting a variety of materials, and the latest advancements in insert technology have led to increased productivity and cost savings for manufacturers.

One of the notable innovations in U drill insert technology is the development of Carbide Milling Inserts advanced coating materials. These new coatings provide enhanced wear resistance, improved heat resistance, and reduced friction during machining operations. As a result, U drill inserts with these coatings have a longer tool life and can operate at higher speeds and feeds, which ultimately leads to increased productivity and reduced downtime for tool changes.

Another important advancement in U drill insert technology is the optimization of geometries and cutting edge designs. Manufacturers have been able to create inserts with more efficient chip-breaking capabilities, resulting in improved chip control and reduced cutting forces. This not only leads to better surface finishes and dimensional accuracy but also allows for more aggressive cutting parameters, further boosting productivity and lowering production costs.

Additionally, innovations in U drill insert technology have led to the introduction of multifunctional inserts that are capable of performing multiple operations in a single tool. These inserts feature complex geometries and cutting edge profiles that allow for drilling, chamfering, and even thread milling in a single pass. This level of versatility not only simplifies tool selection and inventory management but also reduces cycle times and overall machining costs.

Furthermore, advancements in material technology have led to the development of U drill inserts specifically designed for machining difficult-to-machine materials such as heat-resistant alloys, stainless steels, and hardened steels. These specialized inserts are able to withstand the high temperatures and harsh cutting conditions encountered when machining these materials, resulting in improved tool life and performance.

In conclusion, the innovations in U drill insert technology have brought about substantial improvements in tool performance, productivity, and cost-effectiveness for manufacturers. With advanced coatings, optimized geometries, multifunctional designs, and specialized materials, U drill inserts are now more capable than ever, offering increased efficiency and reliability in metalworking operations.

# by jackjerome | 2024-08-29 11:39

The Ingersoll Cutting Tools event Cemented Carbide Insert was held at the historic Cleveland Public Auditorium.

An improved Carbide End Mills for Steel cutting tool could deliver its improvement in any of three different ways. That tool could be cheaper, it could provide longer tool life or it could deliver greater productivity. IMC Group President and CEO Jacob Harpaz says go for the productivity. Now is the time for this.

That was his message at an Ingersoll Cutting Tools 125-year anniversary event last week. The event was held in Cleveland, birthplace of the cutting tool company. Now based in Rockford, Illinois, Ingersoll is today part of the IMC Group, which also includes cutting tool makers such as Iscar, Taegutec and Tungaloy. In presentations throughout the day-long event, Mr. Harpaz described various offerings in Ingersoll’s milling, turning and holemaking lines to an audience of about 850.

Business is good. After Ingersoll’s sales dropped in ’09, following the crash, the company had sales in ’10 that surpassed ’08. Then, after a flattening from ’11 to ’12, business has been increasing through the past two years. All of this is relevant to his message because many machining facilities have seen something like this same pattern of activity. Business is now strong enough in machining, particularly in North America, that any open time on a plant’s machine tools often can be filled. That means far and away the most lucrative return to get from a cutting tool is an improvement in productivity.

Shops do not necessarily see this, Mr. Harpaz says. Because a cutting tool is a consumable that is purchased again and again, its price is seen frequently, and therefore seems more significant than it might be. In most manufacturing processes, the impact of fixed costs and labor costs are actually much higher.

Specifically, for a representative machined part, he says the cost of machinery represents 26 percent of the cost of machining a part. Overhead represents 21 percent of the unit cost of machining. Labor and raw material account for 28 and 22 percent, respectively. Meanwhile, the cost of cutting tools accounts for just 3 percent.

That such a low share of the total cost comes from cutting tools has significant implications. Dropping the price of the tool by 20 percent, as big a change as this might seem, would deliver only a 0.6-percent unit cost reduction. The seemingly even greater change of increasing the life of the tool by a factor of 2 would save only 1.5 percent. But increasing productivity would increase the number of pieces the shop can produce in the same period of time, meaning the labor cost, overhead cost, and machinery cost per piece all go down. Increasing productivity by 20 percent thus produces a savings of 15 percent overall. Productivity increase delivers far and away the greatest savings, he says, because it is the only type of cutting tool improvement that can affect all the other cost factors.

The Ingersoll event showcased various new or improved cutting tool offerings aimed at this productivity increase. For example, the company’s TC430 whisker-reinforced ceramic insert for turning superalloys is more expensive than carbide tools used to turn these metals, but it is so much more productive that the cost increase is easily justified. (See video of the tool turning Inconel.) A couple of the company’s unusual offerings for productivity include:

The most prominent product line at the event was the company’s “Gold Rush” line, which consists of tools benefiting from a post-coating treatment that enhances performance. Tools in this line can deliver long tool life compared to tools without the surface treatment. However, the more profitable use of the tooling is to let tool life remain steady, he says, and instead use the performance enhancement to increase speed and feed rate. Now is the time to go for productivity.

# by jackjerome | 2024-08-14 10:38

GM Tool Corporation (Elk Grove, Illinois) manufactures plastic, diecast and compression molds. The company has been a custom mold builder since its inception in 1965. Its customers are involved in the medical, automotive, consumer products, appliance and computer industries.

The company also understands the production side of injection molding because, in addition to a stable of commercial customers, it also has its own molding division—called Sun Plastics. That company has been in business for 15 years.

A big part of the success of a custom mold shop is keeping itself ahead of competition. “That used to mean beating mold shops in the region,” says GM Tool’s plant manager Ken Moeller. “Today that competition is global.”

For GM, the way to compete is to focus on the tough jobs. “The easy work goes overseas or south of the border,” he adds. “What’s left are jobs that demand the highest skills.” So to play in this market, GM Tool, and companies like it, must not only be good metalcutters, they must also be heavily slanted toward engineering.

While Ken Moeller is responsible for the manufacturing side of GM Tool, his nephew Rick Moeller runs the engineering and programming. GM Tool has seen commercial demands and available technology change its approach to the business. The company has evolved an effective business plan that could be relevant to many other shops in increasingly competitive markets.

For a custom mold builder such as GM Tool, the competitive edge flows from engineering. “Our shop is run basically with engineering,” Rick Moeller says. “Data is crucial to development of the tools we build. Our design engineering is done on a Unigraphics platform. It also generates the tool path for our machines. Engineering and machine programming are critical skill areas for our mold shop.”

The output of this strong engineering and programming focus is the ability to, in effect, automate much of the core and cavity machining. Of course, that means carrying the sophistication of the CAD/CAM system to the shopfloor.

DNC is the carrier of this information to the machine tools. GM Tool has been downloading programs to PCs for dissemination on the shop floor for almost 15 years. “We were very early into DNC,” says Mr. Moeller.

Making molds is among the most complex metalworking applications. It involves numerous operations including, in GM Tool’s case, high speed machining of cores, cavities and graphite electrodes for EDM.

Each of the manufacturing process steps depends on the accuracy of the preceding operation. “We try to look at the process as a continuum,” says Mr. Moeller. “At each juncture we look at what is the best technology to bridge to the next step. Of course, as a custom molder, we don’t get second chances. It has to work.”

While this pressure to make it right the first time is often manifested in shops as conservative practice or a resistance to change from the known, GM Tool approaches the problem differently. To keep moving forward, but at the same time keep risk to a minimum, the company does its homework on a potential new tooling, process, or automation enhancement before it becomes integrated into the shop.

To make sure the shop has confidence in its process, rather than letting the process be a limit on capability, GM Tool invests in good quality equipment. The hope is if everything is done correctly upstream, the actual machining of the mold is almost anti-climactic.

About 5 years ago, GM Tool invested in a high speed machining center to improve processing of graphite electrodes for the EDM operations. The company installed an OKK machining center and, because of high speed machining techniques, saw a huge reversal of what was once a bottleneck.

“High speed changed our entire electrode machining process,” says Mr. Moeller. “We applied the Erowa modular workholding system to further automate this part of the mold making process. It has eliminated our need for manual EDM machines. All of our equipment is CNC with orbiting capability and other features to get the finishes demanded by our customers.

“Before getting into high speed graphite milling, we basically machined electrodes by hand or using laminates,” continues Mr. Moeller. “The tool path for machining electrodes is downloaded directly from engineering. Now the operator has time during the machining cycle to perform other tasks. We have much more unattended machining time available with our high speed graphite milling operation.”

High speed machining techniques are also applied to core and cavity production. The company has a Makino V55 for semi-finishing and finishing operations. Like the graphite milling system, automation of the metalcutting process frees up the operator for additional Seco Inserts tasks.

In the research into high speed machining, with an eye toward lightly attended or unattended operation, GM Tool knew eliminating variability was critical. This is especially true in mold manufacturing because there is no second chance.

Toolholders are one important area of the high speed machining process that got the attention of GM Tool. “Many shops will scrimp on toolholders,” says Mr. Moeller. “In an effort to save a couple of dollars up front, they may end up spending many times more than was saved over the long haul.”

According to Mr. Moeller, GM Tool conducted an extensive search for the right toolholder for the shop. The machine operators were included in the research for the toolholders. “We looked at many different systems of holders, including shrink fit. Our Carbide Milling Insert decision boiled down to ease of setup and operation of the hydraulic toolholder.”

For its high speed metalcutting operations, GM Tool chose its hydraulic toolholders from Schunk (Morrisville, North Carolina). Applied on the Makino machining center, the holders are HSK 63, and GM Tool had them balanced at 20,000 rpm to a 2.5g rating. “Having Schunk certify the balance spec of the toolholders was, in part, a requirement of the warranty on the Makino V55,” says Mr. Moeller.

Matching the right technology to a given application is the art of metalworking. For the requirements of GM Tool, the range of cutting tool sizes that can be accommodated by hydraulic toolholders was an important consideration. Using collets, a single toolholder can be used for numerous sized cutters. This, of course reduced the number of toolholders needed.

“One important consideration for using hydraulic toolholders,” says Mr. Moeller, “is they force you to use cutting tools that are highly accurate. The tolerance between the stroke of the hydraulic toolholder and the OD of the cutter is very small. A ½-inch diameter cutter better be very close to ½-inch toolholder tolerance, or the holder will not clamp it as securely. Moreover, the collet system allows us to interchange inch and metric tools sizes if necessary.”

The hydraulic toolholder works by using fluid to compress an internal membrane within the holder body. The hydraulic fluid delivers uniform pressure around the membrane allowing it to compress equally around the periphery of the cutting tool. Basically, that’s how the hydraulic toolholder delivers its high concentricity specs.

In operation, the concentricity of the hydraulic toolholder delivers runout accuracy of 0.00012 inch or less. This translates directly into cutter tool life increases because the chip load on each cutting flute is more uniform.

Using high speed machining techniques such as GM Tool does, the depth of cut is relatively shallow, which makes having a balanced chip load critical. If one of the cutter’s teeth is carrying a heavier load than the others, it will result in premature failure of the cutter, hence shorter tool life. In untended or lightly tended operation, it is vital that tool wear be predictable.

Another benefit of GM Tool’s hydraulic toolholder system is rigidity. Rigidity plays an important role in predictable tool life as well as runout. An HSK interface, with its dual contact face and taper design, provides GM Tool with a rigid connection that is stable both radially and axially. It also provides reliable repeatability when changing tools from the automatic tool changer. Some of the finishing routines can run 15 hours, and for unattended machining cycles it is critical that tool changes repeat accurately.

GM Tool’s machining centers are equipped with through-the-tool coolant capability. The hydraulic toolholders are designed to accommodate this. Both air and coolant can be applied through the toolholder and cutting tool, depending on the material being cut.

“A big advantage for us with this system,” says Mr. Moeller, “is the simplicity of assembling a tool, especially if there is a reduction collet involved. An operator simply slides the collet into the hydraulic chuck bore and then inserts the tool. A turn of the T-wrench and the tool is assembled. The fit is such that no O-rings or bushings are required for through-the-tool coolant use. Even the depth of the tool in the chuck is adjustable.”

Like most custom mold builders, GM Tool faces the dreaded customer driven inverse curve of shorter lead times for increasingly more complex molds. To succeed, the company has made the engineering end of the process paramount.

At the same time, measured use of automation in the machining end of the business allows the shop to precisely duplicate what engineering designs. It’s almost a reverse of the way mold shops have historically worked.

The use of high speed machining techniques, along with powerful engineering and machine tool programming software, has helped GM Tool realize a general reduction in throughput of 30 percent over the company’s previous methods. Applying technology is more than just buying good tools. It’s about using good tools effectively for the application with a willingness to look hard at new ways to improve.

# by jackjerome | 2024-07-25 10:36

Mapal’s Tritan-Drill series of three-edged drills now includes an  HSS version for small-series production.

According to the company, the shape of the main cutting edge makes the HSS drill robust even in difficult conditions.Stable cutting edge corners reduce damage to the cutting edge for smooth machining. The coating of the drill suits a range of different Carbide Cutting Inserts materials and increases tool life.

The drill features point Vargus Inserts geometry designed to eliminate piloting and center-punching. According to the company, it achieves higher feed rates than twin-edged HSS drills. With a pronounced tip reducing the chance of slipping over the chisel edge, it can also be used with hand drilling units. Diameters range from 8 to 40 mm.

# by jackjerome | 2024-07-17 10:59