CARBIDE INSERT,DRILLING INSERT,CARBIDE INSERTS

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Mack Tool and Engineering is a successful South Bend, Indiana, contract shop that primarily serves customers in the aerospace, defense and medical industries. It taps a wide range of advanced equipment to machine parts from materials such as aluminum, slot milling cutters stainless steel and high-nickel-content alloys that often have a variety of application-critical features. Joel Christensen says micro grooves are features that fall into that category, and they require tight tolerances in terms of width, corner radii and surface finish.

Mr. Christensen is a setup machinist in the shop’s two-axis turning center area, which has a couple of Mazak Quickturn Nexus 200 machines and a Mori Seiki SL-203. He says that because micro-groove specifications have become increasingly stringent over the years, he has considered new, more effective ways to machine them. Mr. Christensen points to a part the shop produced a few years ago that required a 0.02-inch-wide, full-radius groove. At that time, the decision was made to modify an existing Swiss-type toolholder and inserts for use in one of the two-axis turning centers. This required in-house grinding operations to add the full radius to the end of the inserts as well as shimming of the toolholder. In the end, the modified tool would produce the groove, but insert life was limited and unpredictable. Mr. Christensen says he sometimes was able to complete only five parts before the tool would break.

When this job returned for the third time, Mr. Christensen was given the okay to try a different grooving solution. He was aware of the Thinbit brand of grooving tools from Kaiser Tool (Fort Wayne, Indiana) and ordered a toolholder and a pack of Groove ‘N Turn inserts that feature the Dura-Max 2000 sub-micron grain carbide substrate. The inserts were off-the-shelf models that had the proper 0.02-inch-wide, full-radius tip. After switching to this Thinbit tool, Mr. Christensen was able to complete an entire batch of 60 parts with a single insert while achieving a surface finish of 32 Ra. Not only did this enable him to complete the job much faster because no grooving tool inserts needed to be replaced during the run, but it also eliminated the need to modify inserts to match the grooving application.

The success with this part is spurring Mr. Christensen to consider Thinbit tools for other parts that require micro grooves, especially given that he is now programming and choosing tooling for an increasing number of jobs in his area. One example is the aluminum aerospace part shown in photo 1 that requires two sets of three grooves. Thinbit offered another off-the-shelf solution for this part with inserts that have the proper 0.03-inch width and 0.01-inch corner radii. Each plunge of this tool completed a groove with a 32-Ra finish.

Another example is the high-nickel-alloy part shown in photo 2. The challenge with this part is not so much the three full-radius grooves at the end of the cylindrical body. Rather, it is the facing operation required for the boss and the 0.051-inch full-radius groove where the boss meets the body. Although the facing operation presents a heavily interrupted cut, a single full-radius Thinbit insert was able to face the boss and machine the groove for an entire batch of 25 parts, showing just a limited amount of wear afterwards. This speaks to the durability of these inserts, Mr. Christensen says.

Similarly, Mr. Christensen recently ordered and received Thinbit inserts to replace another brand for a face-grooving job he is currently running. The tool has a 0.002-inch full radius with a chipbreaker geometry ground into it. He believes the insert will hold the necessary ±0.0002-inch tolerance that’s required while the chipbreaker will enable this tool to do a better job of preventing unacceptable burrs from forming because it causes the insert to be even sharper. He also sees value in Thinbit Form-A-Groove inserts, which have multiple groove profiles on a single insert. That way, a single tool can create a number of grooves in a single plunge, which would be ideal for the aluminum part mentioned above.

To date, Mr. Christensen has used Thinbit groove inserts in widths ranging from 0.0195 to 0.065 inch with sharp and full-radius tips. In fact, Thinbit tooling has since been used to perform grooving work on the shop’s Swiss-type lathes and turn-mill multitasking machines. Mr. Christensen continues to consider and suggest Thinbit for future grooving work in his area, too,especially as he is becoming more involved in programming and choosing tooling to be used on the two-axis turning centers. Plus, he has recently replaced another cutting tool brand with Thinbit triangular carbide inserts for an ID boring operation. These inserts hold up just as well as those they replaced and are less expensive, he notes.

Mr. Christensen says he’ll do this because there are three aspects of Kaiser Tool—which celebrated the 50th anniversary of the Thinbit brand in June—that he particularly appreciates. First, the company keeps a wide range of grooving tools in stock, offering fast delivery of inserts having various widths and tip geometries. Second, it turns custom tooling requests quickly. Although only a small fraction fast feed milling inserts of Mr. Christensen’s jobs require custom grooving tool profiles, he says Kaiser Tool has turned some of those requests around in a matter of days. Finally, the company provides quality customer service. Mr. Christensen says he receives an email reply or phone call within 15 minutes of contacting Kaiser Tool to ask a question or place an order. The company will even contact him right away even if it isn’t able to provide a quote at that time. Mr. Christensen says he doesn’t always get this type of immediate response from other tooling companies. 


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

When it comes Cast Iron Inserts to cutting insert geometry, most tool manufacturers will immediately begin to describe the macroscopic geometry (physical shape) of the insert. And a research field that has developed rapidly in recent years-the optimization of the microscopic geometry of the cutting edge of the insert-deserves great attention.

At the macro level, the optimization of the blade geometry mainly involves the best shape possible for chip control. According to different workpiece materials and processing methods, using different blade shapes and angles can provide the best results for chip breaking and chip removal from the cutting area. The design and optimization of the macroscopic geometry of the CCGT Insert blade is a fairly mature technical field, and most major tool manufacturers are proficient in this.

It is only in recent years that the development of technology has reached a level that can control the microscopic geometry of the blade. Using advanced processing technology, round, oval or angled cutting edges can be prepared on the cutting surface of the blade, and tiny chamfers or grooves can be introduced into the cutting edge of the blade. With the application of various innovative technologies, people can passivate and measure the blade on a tiny scale, which greatly improves the service life and processing stability of the blade. It can be expected with certainty that future technological advancements will further promote the development of this field and will achieve more significant results.


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

Today, we will introduce to you the requirements when processing carbide inserts for stainless steel.

1. Requirements for Tool Geometric Parameters

The geometry of the cutting part should generally be considered from the choice of rake angle and back angle. When selecting the rake angle, the factors such as chip groove type, chamfering and the positive and negative angle of edge inclination angle should be considered. No matter what kind of tool, the larger front angle must be used when processing stainless steel. Increasing the rake angle of the tool can reduce the resistance in the process of chip removal and clearance. The selection of the back angle is not very strict, but it should not be too small. If the back angle is too small, it will easily cause serious friction with the surface of the workpiece, which will worsen the surface roughness and accelerate the tool wear. And due to strong friction, the effect of work hardening on the surface of stainless steel is enhanced. The clearance angle of the tool should not be too large. If the clearance angle is too large, the wedge angle of the tool is reduced, which not only reduces the strength of the cutting edge, but also accelerates the wear of Cutting Inserts the carbide milling cutter and the drill bit. Generally, the relief angle should be appropriately larger than when processing ordinary carbon steel.

2. Requirements for the Surface Roughness of the Cutting Part

Improving the surface finish of the cutting part of the tool can reduce the resistance when the chips are crimped and improve the durability of the carbide inserts for stainless steel. Compared with processing ordinary carbon steel, when processing stainless steel, the cutting amount should be appropriately reduced to slow down tool wear. At the same time, appropriate cooling and lubricating fluid should be selected to reduce the cutting heat and cutting force during the cutting process as well as prolong the service life of the tool.

3. Requirements for Cutting Some Carbide Milling Inserts Materials

When machining cemented carbide inserts, it is required that the material of the cutting part of the tool has high wear resistance and can maintain its cutting performance at a higher temperature. At present, the commonly used tool materials are: high speed steel and cemented carbide. As high-speed steel can only maintain its cutting performance below 600 °C, it is not suitable for high-speed cutting, but only suitable for processing stainless steel at low speed. Since cemented carbide has better heat resistance and wear resistance than high-speed steel, CNC blades made of cemented carbide materials are more suitable for stainless steel cutting.


The Carbide Inserts Blog: https://latheinserts.edublogs.org

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