CARBIDE INSERT,DRILLING INSERT,CARBIDE INSERTS

CARBIDE INSERT,DRILLING INSERT,CARBIDE INSERTS,We offer round, square, radius, and diamond shaped carbide inserts and cutters.

タグ:Factory

The answer to the question of whether a carbide grooving insert is compatible with different machine tool configurations is a definite yes! Carbide grooving inserts are designed to work in a variety of machine tool configurations, including traditional lathes, CNC machines, and EDM machines. Their versatility is due to their unique design, which combines a sharp cutting edge with a tough substrate material.

Carbide grooving inserts are designed to cut a wide range of materials, including both hard and soft metals. They are especially useful for machining intricate and complex turning inserts for aluminum shapes, and can be used to produce fine details with precision. The cutting edges of carbide grooving inserts are designed to remain sharp for extended periods of time, making them a reliable and cost-effective choice.

In addition to their compatibility with various machine tools, carbide grooving inserts are also extremely durable. They are abrasion-resistant and can withstand high temperatures, making them an ideal choice for heavy-duty production runs. They are also corrosion-resistant and can be used in a variety of environments, making them an ideal choice for applications in wet or corrosive environments.

Overall, carbide grooving inserts are an excellent choice for a variety of machining operations. shoulder milling cutters Their versatile design and excellent durability make them an ideal choice for a wide range of applications. Additionally, their compatibility with a variety of machine tools ensures that they can be integrated into a variety of tool configurations.


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

Insert rupture is devastating to productivity, especially under the pressure of a recently doubled order. Rich Bauer, manufacturing coordinator at McGill Machine Works in Schaumburg, Illinois, was confronted with this issue during a rough-milling application. However, by retooling with new inserts from Ingersoll Cutting Tools (Rockford, Illinois), he says he now achieves eight times the tool life of the previous inserts plus an 80 percent boost in throughput.

Working in a 10-employee machine and fabrication shop that runs 22 hours a day, five days a week, Mr. Bauer was tasked with rough-milling a high-chrome, D-2-wrought stock piece that serves as a wear part in a nail-gun mechanism. The roughly rectangular finished part measures 2.5 inches long by 1.25 inches wide and 0.350 inch thick, with a stepdown to 0.194 inch. More than half of the blank’s original weight is reduced to chips in a roughing operation that includes facing and square-shoulder step milling. This operation accounts for 80 percent of total machining time. Following that are drilling, slotting, and finally, radiusing to eliminate stress-raiser corners. The part is then heat treated to 60-62 HRC and oxide coated.

Although Mr. Bauer was initially using inserts that were designed for high-chrome steels, he says he was lucky to get as many as five pieces out of them before they shattered. He tried easing back the material-removal rate, but that made little difference. He says it took 51 minutes to complete the roughing when running the part on a Kia vx 500 CNC vertical machining center using a 2-inch-diameter, four-pitch face mill and settings of 625 sfm, 10 ipm and 0.050-inch depth of cut (DOC) using synthetic coolant. Under those conditions—or even when slowed down—inserts usually popped every fourth or fifth piece. Increasing the DOC led to chip clogging. The process often generated a pounding sound and created powdery chips characteristic of hard-part machining. 

“Catastrophic tool failure was our main problem, but we were looking to boost throughput as well,” Mr. Bauer says.

The impetus of change began with a promotional email from Ingersoll introducing its new Di-Pos Hexa high-performance face mill. After calling field representative Jarett Johnson for a trial, Mr. Bauer had a new tool in hand, along with recommended parameters and advice to turn off the Carbide Drilling Inserts coolant.

Mr. Bauer says he was too busy to try the new cutter right away, but he did so a couple days later using the supplied parameters. Although Mr. Johnson and Mike Toleman, his distributor at Quality Tools and Abrasives, offered to assist, he says it was so simple a retooling that he did not need much hand-holding.

For the trial, he dialed in Mr. Johnson’s recommended parameters and followed his advice to turn off the coolant. The settings for a 2-inch-diameter, six-pitch Di-Pos Hexa were 500 sfm, 40 ipm and 0.075-inch DOC. They led to a 28-minute cycle time and six-times-longer insert life. Surface finish came out well within the 30- to 60-microinch spec. Despite the higher removal rate, the spindle load meter rarely topped 50 percent and the operation ran more quietly. Uniform C-shaped chips were produced, bar peeling inserts indicating a very free-cutting action.

“Running dry on such a punishing material may seem counterintuitive, but cutting fluids can often create thermal shock that can crack the coatings on today’s high-performance inserts,” Mr. Johnson says. “Moreover, the Di-Pos Hexa tool is so much cooler running that cutting fluids are not needed in the first place.” 

After some experimenting, Mr. Bauer backed off the feed to achieve a 25-microinch finish, settling at 20 ipm and leaving everything else the same. That change increased cycle time to 39 minutes, which was still 25 percent better than before. Tool life also increased—the shop is now getting the same life out of one tool that it previously got out of eight. These became McGill’s standard parameters for the job. Now, rupture is a thing of the past. Instead, the company experiences a failure mode of gradual flank wear, making the process more secure, Mr. Bauer says.

“Floor-to-floor time has improved even more because of the reduced tool-servicing downtime,” he says. “We get more than an entire shift out of a set of edges and never get a rupture.” He estimates that the retooling is saving McGill about $10,000 a year from all sources.

Several key factors contribute to the Di-Pos Hexa’s improved performance on D-2, despite the material’s proclivity to heat hardening. “First, the inserts have positive rakes both axially and radially,” Mr. Johnson says. “The cutting action is more cleaving than scraping, which knocks down cutting forces and resulting heat.”

The second factor is an advanced coating that reduces friction and insulates the insert substrate from machining heat. “The coating diverts machining heat into the chip as it is flung away from the cutting zone, leaving the tool and workpiece cooler,” Mr. Johnson says. “On average, over hundreds of applications, the coating has improved insert performance 35 percent, even on difficult materials.” 

Other features of the Di-Pos Hexa are thick inserts and large gutters in the cutter body, which together enable cuts as deep as 0.230 inch without chip clogging. “Higher cutting depths are especially important on heat-hardening-prone materials such as D-2,” Mr. Johnson says. “Unless the cutting edge reaches beneath the hardened surface and into the softer material right away, you are doing hard-part machining whether you realize it or not.” 

McGill turned out to be one of the first users of the Ingersoll Di-Pos Hexa. The tooling company introduced it recently for square-shoulder milling and aggressive ramping at depths ranging to 0.230 inch. Though the inserts are two-sided, the cutting edges are positive-rake both axially and radially.

To keep the shop running, distributor Quality Tools and Abrasives keeps an on-site vending machine stocked with all the inserts the company uses. Ingersoll inserts represent about three-quarters of McGill’s insert purchases.


The Carbide Inserts Blog: http://itime.blog.jp/


The Advantages Of CBN Inserts

* Long Tool Life.
CBN cutting tools have properties that resist chipping and cracking and provide TCMT Insert uniform hardness and abrasion resistance in all directions. They may outperform conventional cutting tools by as much as 50 times. Reduced tool wear results in closer tolerances on workpieces, and fewer tool adjustments keep machine downtime to a minimum.

* High Material -Removal Rates.
Because CBN cutting tools are so hard and resist abrasion so well, CBN cutting tools can withstand the high temperatures created by increased speeds and feeds. This results in higher material-removal rates with less tool wear, which reduces the total machining cost per piece.

* High-Quality Products.
Because the cutting edges of CBN cutting tools wear very slowly, they produce high-quality parts faster and at a lower cost per piece than conventional cutting tools.

* Good Surface Finish.
Surface finishes of less than 10 microns. are possible, which often eliminates the need for relatively slow finishing operations such as conventional grinding.

* Lower Cost per Piece.
CBN cutting tools stay sharp and cut efficiently through long production runs. These results in better control over workpiece shape and size and fewer cutting-tool changes. This lowers manufacturing costs TNMG Insert per piece by reducing inspection time and increasing machine uptime.

Related search keywords:

CBN inserts, cbn inserts price, cbn inserts manufacturers, cbn inserts for stainless steel, cbn inserts hardness, cbn inserts speeds and feeds, cbn inserts china, cbn carbide inserts, cbn inserts with chipbreaker, cbn inserts for cast iron, cbn inserts, cbn insert, cbn inserts for hard turning, cbn inserts for turning, cbn grooving inserts, cbn lathe inserts, cbn inserts machining, cbn inserts materials, pcd and cbn inserts manufacturers, cbn pcd inserts, cbn round inserts, solid cbn inserts, cbn tool inserts, cbn turning inserts, pcbn inserts



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

このページのトップヘ