oscarspenc

Heule Precision Tools’ BSF tool for automated, high-volume back-spotfacing and counterboring enables a counterbore ratio of 2.3×D. The tool is suitable for diameters ranging from 6.5 to 20 mm and avoids the need to turn over the workpiece. Since the machining is done from the same side as the bore is drilled, it is also possible to apply spot faces or counterbores in areas that are difficult to access, such as bores between the forks of yokes or screw-head countersinks. The tool can cut aluminum, high-grade steel, Inconel and titanium, and its components are designed for ease of replacement in the case of wear. Designed for use on a machine VBMT Insert equipped with internal coolant of approximately 20-bar working pressure, Carbide Inserts the blade unfolds by activating the spindle with an initial rpm and by the gravity of its own weight, and is folded back on demand with an impulse of the internal coolant.

Improving cycle time, chip control and tool life can be a challenge during heavy turning of gummy metals. In fact, it is common to sacrifice at least one of these factors, if not two. For instance, cutting deeper improves chip control and speeds up the operation, but it also raises the risk of rupturing the tool at any moment. Cutting shallower may prevent tool rupture, but it also slows down the operation, requires more passes and can create long, stringy chips that are hard to manage.

In the case of AWC Frac Valve, sudden edge failure often prevented the company from manufacturing even a single complete valve piece before its tooling failed. By retooling the application with a new insert from Ingersoll Cutting Tools (Rockford, Ill.), the company tripled the material removal rate and more than doubled tool life while eliminating tool failure.

AWC Frac Valve, a division of Archer Well, manufactures very large valves for the oil and gas industry in its 35-man shop located in Conroe, Texas. The company, running 24/5, uses a Doosan 400LM turning center for heavy-duty turning and facing operations in which a 480-pound billet of gummy 4130 steel is reduced to a 250-pound valve bonnet.

To produce this piece, the company used a conventional CNMG negative-rake tool that rarely lasted through one part. “We had to keep two back-up tools in the turret just to keep things going when one tool popped,” says Jim Beaver, AWC’s assistant production manager. “Often, the tool would rupture midway through the first piece.”

Such short tool life was not an option for Mr. Beaver, who was charged with implementing plant-wide continuous improvement. Instead, he set a new tool-life requirement for the application of at least two pieces per edge. He pointed out the challenge to the company’s Ingersoll rep during their regular weekly plant walk-through. The scale of the operation and the cutting forces involved prompted the rep to bring in Eric Strieby, Ingersoll field turning product manager. Under Mr. Strieby’s guidance, AWC tested the Ingersoll CNMX Gold Duty indexable coated carbide insert on-site.

“It was like a beta test, but on a commercialized tool,” says Kirk Cudd, AWC production manager. “Should the tool break during the test, we wouldn’t have to pick up the tab.” By contrast, he says, many tool providers offer on-site testing and reduction to price, but only after the customer purchases the tool and pays for any replacements.

CNC lead man Ben Molinar ran the test on live parts through heavy OD roughing, OD finishing and facing on 4130 steel. The results appear in the table below. For comparison, Mr. Beaver tested the latest CNMG inserts from two other providers, but neither could meet the two-pieces-per-edge requirement consistently.

Once the tool proved out operationally at the parameters established in the test, Mr. Beaver did some fine-tuning. He eliminated the two back-up tools from the turret and ramped up the depth of cut to 0.325 inch for turning and 0.225 inch for facing. The inserts now last through at least two parts with no ruptures.

“Now the failure mechanism is gradual wear, not fracture, and the indicator for edge change is simply loss of finish,” he says. As a result, tool-related production stoppages disappeared altogether and tool servicing labor costs dropped significantly. For this job alone, Mr. Beaver says the savings associated with the retooling is $75,000 per year.

The Ingersoll CNMX tool’s seating scheme enables improved insert geometry—a key factor slot milling cutters that helped it succeed in the valve bonnet application. According to Mr. Beaver, “the big, wide front edge really breaks up the chips on a pretty gummy metal.” The big chips peel off in easily controlled “six and nine” shapes.

Compared with conventional CNMMs and CNMGs, the new seating arrangement in the CMMX makes it possible to get two sides plus aggressive, positive geometry in the same insert—something never available before, says Ed Woksa, Ingersoll’s national turning product manager. “You can cut deeper without overloading the insert and still get the second side.”

CNMMs feature a neutral rake with a negative land at the cutting edge for improved strength, chip breaking and chip flow, which enables application of higher feed rates. However, these inserts must deep hole drilling inserts be single-sided because positive-rake tools cannot be flipped without damaging the cutting edges with the clamping forces. By contrast, CNMGs that are designed for heavier cuts are two-sided, yet they normally have neutral or slightly positive rakes ranging from 0 to 6 degrees, which raises cutting forces.

Unlike flat insert seats found in conventional toolholders, the Ingersoll CNMX seating scheme is based on four “rest pads” on the insert that mate with dimples in the seat. The cutting edge can be 5-degrees positive, which enables freer cutting, without risk of clamping damage because the rest pads, and not the cutting edges, bear the clamping forces.

“Tooling performance aside, Ingersoll was easier to work with on a very risky operation,” Mr. Beaver says. “Besides, we were looking for a tool-life improvement only and wound up with a cycle-time savings as well.” Looking ahead, he sees at least ten other heavy-turning jobs in which the new Ingersoll CNMX will likely bring about the same improvements. 

What’s the standard tolerance of mold in CNC programming process?

The CNC programming department of the mold factory develops clear processing techniques and rod peeling inserts standards and performs standardized operations in the production process to improve work efficiency and reduce errors.
1.the former mold
a.Hot position
1 The size required for assembly must be based on the number.
2 Plane: The machining program is based on the number of dimensions, and the CNC operator measures the number according to the tolerance of the drawing size.
3 Side: The machining program is open for compensation. The unilateral side is left with a 0.02mm balance. The operator uses the needle gauge to fit tightly. The tolerance is guaranteed to be within 0.015~0.005mm. The other dimensions are based on the size of the 3D image.

b. Insert buckle
The side of the buckle of the insert shall be processed according to the shoulder milling cutters procedure, and the size shall be determined according to the size, and the depth (Z value) of the buckle of the insert shall be determined according to the number of dimensions, and the operator shall use the calibration gauge to measure the depth, and the tolerance requirement shall be 0.01 mm.

c.Glue size
The finishing procedure for all glue positions requires 0.02 mm on one side (except for special cases), and 0.15 mm on one side with fire pattern requirements for processing EDM lines.

d. Insert and touch the bit
Under normal circumstances, the front mold core is of a proper size, and the rear mold core retains the remaining amount.

e.Side lock position
The bottom depth (Z value) of the side lock position is made to be a standard size, and the side edge machining program of the side lock position needs to be compensated for one side to leave a 0.02 mm test fit. The operator is tightly matched according to the figure size, and the tolerance is guaranteed to be unilateral from 0.015 to 0.005 mm. Inside.

?2.the post mold

a.Row slot
The depth (Z value) of the row position slot shall be determined according to the number of drawings. The operator shall use the table to measure according to the tolerance of the drawing, and the two sides of the row groove shall be processed according to the drawing size. The program processing shall be compensated for one side and 0.02 mm. The test is equipped with the block gauge, and the tolerance is guaranteed within 0.015~0.005mm on one side.

b.Insert buckle
The side of the buckle of the insert shall be in accordance with the number of drawings, and the depth (Z value) of the bottom shall be in accordance with the number of dimensions. The operator shall use the calibration meter to measure the tolerance to a depth of 0.01 mm.

c.Mold hole position (hiding CORE bit)
The programmer does the light knife program and needs to open the compensation side to leave 0.02mm margin. The opening compensation operator measures according to the number of drawings. The single side is 0.005~0.01mm, which is convenient for assembly.

d. Glue size
All glue position finishing allowances are 0.02mm (except for special requirements).

e. Insert and touch the bit
Under normal circumstances, the rear mold needs to leave more than +0.02~0mm margin. The position of the rear mold with the row position must be determined according to the size of the row, and the position of the mold core after the matching of the row position needs more margin.

3.the mold convex CORE

a.When roughing, leave 0.5mm margin on one side, and when inserting the frame insert to the bottom to use rough machining CORE, leave 10mm at the bottom straight position for the operator to check if the roughing is loose and need to be quenched. The profiled convex CORE bottom is left straight for 10mm for finishing after quenching.

b.All glue positions are 0.02mm during finishing (except for special requirements), and the position to be inserted and penetrated is +0.02~0mm.

c.Convex CORE shape finishing, when the programmer makes the light knife program, the compensation is the 0.02mm margin on one side, and the operator can measure the tolerance of one side from 0~ –0.005mm according to the number of drawings.

d. The problem of the irregular shape of the mold insert (convex CORE) is detailed in the latter part.

4. row position, insert

a.When receiving the workpiece, the programmer should measure the external dimensions of the workpiece to avoid problems when the number of hits in the middle and the single side. The programmer needs to discuss with the operation group according to the shape of the workpiece, using a secure clamping method and a method of hitting the number. See the latter section for details.

b.The row position and the front and rear mold cores have matching positions, and the row position needs to leave 0.02 mm margin for FIT.

c. All glue positions are 0.02mm on one side (except for special requirements).

5. oblique top

According to the shape of the workpiece and the operation group, using a secure clamping method, the number of touches, all the glue positions are 0.02mm on one side (except for special requirements). Please add WeChat public number: industrial intelligence (robot info) Ma Yun are paying attention

6. mold processing

a.Mold
(1) The base word (chamfering) on the mold blank drawing should be consistent with the reference on the mold blank. In order to avoid misunderstanding, the machining chaos occurs, and the reference edge faces the direction of itself during programming.
(2) The machining positioning of all the templates establishes the machining coordinates by zeroing the guide hole in the near reference angle.
(3) Z-number hits definition: All templates are processed in forward and reverse directions. The number of touches at the bottom of the mold is zero. For workpieces with special requirements, the programmer needs to explain clearly with the relevant personnel and clearly indicate on the program list. The zero position of the mold embryo.

b.A board
(1) When the mold frame is finished, when the bottom of the mold frame is processed, the size must be made according to the size of the paper. The CNC operator uses the calibration of the drawing according to the tolerance of the drawing. The tolerance is +0.01~+0.02mm. The finishing process of the frame edge requires 0.02mm margin for the one side of the compensation. The operator fits the block gauge according to the size of the drawing. Tolerance Guaranteed 0.02 ~ 0.01mm on one side.
(2) The side lock position is made according to the bottom of the figure size. The side block gauge is tightly matched, and the tolerance is guaranteed within unilateral +0.015~-0.01mm.
(3) The bottom of the insert groove should be the number of quasi-sizes, and the side should be tightly tested with the block gauge. The tolerance is guaranteed within unilateral +0.015~ +0.01mm.
(4) The size of the shovel chicken trough and other dimensions are processed according to the plan.

c.B board

(1) Formwork finishing, the number of the standard size of the program processing frame is used, the CNC operator uses the table to measure according to the tolerance of the drawing, the tolerance is +0.01 0mm, the frame edge finishing, the program needs to open the compensation side 0.02mm The margin, the operator needs to use the block gauge according to the size of the figure, the tolerance guarantee – within 0.02~0.01mm on one side.
(2) The depth of the (Z value) at the bottom of the groove of the mold frame should be processed according to the drawing size. The operator uses the calibration meter according to the tolerance of the drawing. The tolerance is +0.01~+0.02mm, and the side program needs to open the compensation sheet. With a 0.02mm test fit, the operator needs to use the block gauge to tightly match the tolerance to unilateral +0.015~+0.01mm.

d Thimble panel:
(1) When the position of the ejector countersunk head is deep processing, the depth needs to be 0.02mm deep, and the operator uses the thousand points card to measure the tolerance, the tolerance is 0.02~0.01mm, and the side of the thimble countersunk head position needs to be processed to the size.
(2) The processing dimensions of the slanting top base assembly position are determined by the bottom of the ejector panel during the processing, and the operator uses the comparison table to measure the number while the side processing size is in place.
(3) The other positions are processed in accordance with the size of the 3D map.

e. thimble bottom plate:
(1) The size position required for the assembly of the insert, the operator needs to be tightly fitted with the block gauge, and the other positions are processed according to the size of the 3D drawing.
(2) C board: According to the 3D drawing size, the quasi-size is processed, and the working surface and the processing direction are selected by the boring machine group in the positive direction of the A code.
(3) Nameplate: It is required to be carved according to the requirements of 3D drawings.
(4) Upper fixing plate: The size of the mounting position is required for the assembly. The size of the upper fixing plate must be processed at the bottom of the upper fixing plate. The operator needs to use the meter to measure the number, while the side processing needs to open the compensation. 0.02mm, the operator needs to use the needle gauge to ensure that the single side is +0.015~+0.01mm, and other sizes are processed according to the 3D drawing.
(5) Lower fixing plate: There is the size required for the assembly of the insert. The bottom of the lower fixing plate needs to be processed to the quasi-size. The side is required to be tightly packed with the block gauge, and the other dimensions are processed according to the 3D drawing.

f.programming:

(1) Definition of steel processing coordinates: the rectangular reference is toward the person, and the square reference is toward the lower right corner. In a normal case, all the steel materials are programmed with X and Y points as 0, and the Z value is 0 at the bottom to establish the machining coordinates. (See CNC machining coordinate definition and clamping direction standard drawing 1, 2, 3)
(2)The roughing process is 0.5mm on one side, and the top of the mold is required to be quenched. It is easy to clamp during finishing.
(3) Finishing the bottom of the mold, avoiding the front of the mold, PL, glue position, etc.
(4) Mould tube position: The tube position programming of all front and rear mold cores is 0.01mm small.
(5) Planar PL processing: The program processing should be dimensioned according to the size of the drawing. The operator needs to use the calibration tolerance of the calibration meter to ensure that it is within +0.01~0mm.
(6)The arc surface PL processing, the programmer makes the test procedure, the program list indicates the smooth bottom plane PL, and the light knife processing program makes the standard size.

When the front and rear mold processing coordinates are defined, the rectangular reference is toward the person, and the square reference is toward the lower right corner (0 in the X and Y sides and the bottom is 0 in the Z), as shown in Figure 1, Figure 2, and Figure 3:

The convex CORE hit number is shown in Figure 4 and Figure 5;

The number of row seats is as shown in Figure 6:

The number of mold collisions is shown in Figure 7:

I recently visited Sandvik Coromant's headquarters in Sandviken, Sweden, (and insert production facility in nearby Gimo), during a global press event with editors from 20 countries. 2017 marks the 75th anniversary of Sandvik Coromant, so the company wanted to present a few new recent developments in tooling technology, three of which I think I succinctly documented in this tweet I posted at my @MMS_Derek handle during the event:

Two of these I’d call technologies “for the now,” while the other is a technology “for the future.”

Let’s start with one “for the now.” Prime Turning, literally and figuratively, is a genuinely new approach to turning. For essentially, well, ever, turning has been performed with the part rotating and the stationary cutter moving longitudinally down the Z axis (or X and Z axes for profiling) toward the chuck. Then, once that pass was completed, the tool would retract and repeat similar passes. Using appropriate tooling and some new programming techniques, Prime Tooling can perform turning in multiple directions using the same tool: longitudinal turning (toward the chuck or away from it), facing and profiling operations.

Sandvik worked with MasterCAM/CNC Software to develop programming techniques as part of the Prime Turning code generator. On the surface, it might not seem too terribly difficult to simply run the tool in the other direction. However, it did present some programming and tool geometry challenges. In fact, Mark Albert is currently working on a story for our June issue that will provide more detail about all this. For example, it will explain why lower cutting pressure during passes made away from the chuck enables higher cut data and material removal rates during roughing. (This operation creates thinner, wider chips and spreads the load and heat away from the nose radius.) In addition, as cutting is performed in the direction moving away from a shoulder, there is no danger of chip jamming, which is common during conventional longitudinal turning toward the chuck.

While I don’t want to steal his thunder here, this video includes example cuts demonstrating the concept.

The company has also developed its CoroPlus tool and software platform to facilitate big data/IIoT efforts (you might have learned about these a few months ago at IMTS). One tool example is the CoroBore, which uses an embedded rod peeling inserts sensor system to enable wireless, automatic fine adjustment of the boring tool’s cutting diameter to speed and simplify setups. Another is the company’s line of Silent Tools, providing in-cut process monitoring and optimization for tools using connected, damped adapters for internal turning of deep features.

In addition, Sandvik’s Promos 3+ data collector monitors tools and operations in real time to help ensure machining safety. Developed by Prometec, Promos 3+ enables on-site or cloud-based monitoring to prevent collisions before they happen, stopping a machine if a tool is missing, breaks or collides with a part or fixture.

Another part of the company’s IIoT offerings is tooling design and planning connectivity with CoroPlus ToolGuide, in which tool and cutting data recommendations can be Carbide Milling Inserts integrated into the CAD/CAM environment, and ToolLibrary, which is built on the ISO 13399 standard that is open for all cutting tool suppliers.

As for the future, Sandvik is combining its knowledge of additive manufacturing powder metallurgy (through the Sandvik Materials Technology division) and cutting tool design knowledge for AM-grown parts (through the Sandvik Machining Solutions division), bridging these with its new Additive Manufacturing Center. This facility uses powder-bed fusion and binder jetting equipment to develop appropriate AM processes to create functional metal parts and explore new concepts in cutting tools.

For example, the AM-grown end mill body shown in one of the photos above is 60 percent lighter than the same design machined via conventional means. One benefit is lighter weight can facilitate higher spindle speeds. The company says testing of some AM-grown tool designs like this one is currently underway, and it hopes to provide test data/details soon (stay tuned).

All of these new tooling developments demonstrate how the company is leveraging its machining and manufacturing experience and knowledge with an eye toward developing new advances in the future. In fact, Sandvik continues to introduce an average of six new tool designs each day. Many of these developments also serve as an example of how the increasing integration of new software technology, as shown with those used for the Prime Turning and CoroPlus platforms, will continue to impact how shops approach machining in the coming years.

IMCO Carbide Tool’s new M936 Pow-R-Feed end mills are designed to provide faster part cycles and milling speeds in steels, stainless steels and titanium slot milling cutters machined on three-axis to five-axis CNCs, regardless of horsepower. The company displays the end mills in booth 2245 at Carbide Turning Inserts Westec 2023.

The tools enables users to make toolpath moves without slowing down, as well as helical enter, ramp, slot and peripheral mill at rapid feed rates. Its specialized flute and core geometries and tough carbide core enable aggressive cutting parameters, while a proprietary end face enables aggressive ramping and helical entry parameters. According to the company, the end mill’s flute design and modern coating make it virtually impossible to clog.

Control Micro Systems (CMS) has developed turnkey laser marking and cutting systems for the medical industry. The company’s Ytterbium fiber (1,064-nm), frequency-doubled Nd:YVO4 (532-nm) and frequency-tripled Nd:YVO4 (355-nm UV) lasers effectively mark both LDPE and HDPE materials. This capability is beneficial for manufacturers of products such as endoscopic guidewire devices, which are frequently marked with brand and model information as well as measurement scales. The results are sharp, durable and represent a cost savings compared to inkjet or pad printing processes, CMS says.

The high-power Ytterbium fiber laser can also be used to terminate and seal-braid 304 and 316 stainless guide wire that is pulled from a reel and cut to length. The laser not only cuts through the braided steel, but welds the individual Carbide Turning Inserts strands together to prevent unraveling, creating a semispherical tip on each end. 

Another potential application is the cutting of eyelets at the ends of latex catheters. According to CMS, the eyelets can be cut with little to no debris or remelt material. Instead, the latex in the eye can be ablated using the company’s CO2 (10,640-nm) laser with high-speed galvanometer beam delivery to completely remove all material in under a deep hole drilling inserts second.

Reducing CO2 greenhouse gas emissions has become the goal of the world, and now many places are discussing to levy CO2 emission tungsten carbide inserts tax. Due to the emergence of new fields, and people have to adapt to the existing fields, the above requirements also have a considerable impact on the research and development of machining tools. This is because more than ever, there is a need to replace drives, update lighter materials, and save energy and resources. R & D personnel see great potential for design modifications to tools, new coatings, new machining strategies, and digital solutions that respond in real time to a variety of conditions within the existing framework.

The current trend is to use these materials in new light aluminum lithium alloys, which will soon overwhelm traditional cutting tools and occupy an absolute advantage. Therefore, the demand for special high-performance tools for such applications will continue to increase. For example, aircraft tube process inserts parts made of aluminum alloy are usually processed up to 90%. According to the required part geometry, many grooves and cavities need to be milled out of the metal to ensure stability and reduce weight. In order to produce high quality parts economically and efficiently, high speed cutting (HSC) is needed to process the parts, and the cutting speed can reach up to 3 ? 000 ? M / min. Too low cutting parameters will lead to chip accretion, which will lead to rapid wear and frequent tool change. Because of the long running time of the machine tool, the cost is high. Therefore, machine tool operators specializing in aluminum processing have good reasons to require their cutting tools to obtain cutting data and tool life above the average level, as well as extremely high machining reliability.

We have shown how to deal with these complex requirements. The 90 ° milling cutter is equipped with a new type of indexable blade. It uses a new PVD coating, manufactured using the “hipims method.”. Hipims stands for “high power pulsed magnetron sputtering”, a technology based on magnetron cathode sputtering. The unique feature of this physical coating process is to form a very dense and smooth PVD coating, which can reduce the friction and the tendency of chip accretion. At the same time, this method improves the stability of the cutting edge, and increases the resistance of the back face wear, thus achieving the maximum metal removal rate. Field tests have shown that hipims indexable blades have advantages over standard types. Tool life increased by 200%. The demand for high-performance cutting tools for processing aluminum alloy is growing, especially in the aviation industry and automobile industry.

Dynamic milling: a milling strategy focusing on efficiency

Many industries (especially the supply industry) are facing the pressure of improving the processing stability, accelerating the processing speed, reducing the processing cost and ensuring the processing quality. At the same time, the requirements of machining reliability and cost efficiency are also strict for surface quality and dimensional stability. In addition, the demand for lightweight or heat-resistant materials is also growing. However, due to these properties, these materials from the ISO m and ISO s material groups are often difficult to accurately process. Dynamic milling provides solutions for this field, while ensuring production efficiency and machining reliability, which is why more and more metal processing companies rely on this method.

The difference between high performance cutting (HPC) and high dynamic cutting (HDC) is the movement and force of milling cutter. In the high performance cutting process, when the milling tool moves, the cutting depth is relatively small; in the high dynamic cutting process, the CAD / cam control system controls along the path of the tool during the processing of the workpiece shape (Figure 1). This prevents or at least reduces non cutting time. Moreover, the cutting depth of high dynamic cutting is much larger than that of traditional high-performance cutting, that is, the stroke distance is reduced, because the whole tool length can be used.

Figure 1 dynamic milling strategy requires appropriate workpiece, milling tool, machine tool and CAD / CAM system

In the process of high performance cutting, the envelope angle is often very large. Therefore, the force in the process is also very large. This will speed up the tool and machine spindle wear. On the other hand, dynamic milling is characterized by high machining stability and long tool life. Generally speaking, the envelope angle of high dynamic cutting is very small, that is to say, the force of the tool and machine tool is much smaller than that of high performance cutting. Compared with high performance cutting, high dynamic cutting has higher cutting parameters, smaller non cutting time and greater machining stability, so its metal removal rate is very high.

Adaptive feed control: using real-time parameters to optimize cutting parameters

For a long time, automation, digitization and networking technology have been widely used in many metal processing fields, and are very popular. In particular, the hardware and software used to collect and analyze real-time data have made a huge leap in performance. Software tools demonstrate how these tools provide numerous opportunities for optimizing processes (Figure 2). Adaptive feed control analyzes the input data of machine tool in real time and adjusts the machining accordingly. This answers a key question for many users. That is, how to give full play to the benefits of the machine tool without major changes to the process or complex reprogramming? The software can greatly shorten the processing time of a single piece. The software has been integrated with the existing control program, and the data in the program has been applied to the machining process.

Figure 2 dynamically adjust the feed according to the cutting conditions. In this way, the production time of a single piece can be shortened and the processing reliability can be improved

During the first tool cutting, the computer “learns” the idle output of the spindle and the maximum cutting efficiency of each tool. It then measures the spindle output up to 500 times per second and automatically adjusts the feed in each case. That is to say, the machine tool always runs with the maximum feed amount of each tool. If the cutting conditions change (cutting depth, machining allowance, wear, etc.), the computer will adjust the speed and output in real time. This not only has a positive impact on the machining time of the workpiece, but also improves the machining reliability with the optimized milling characteristics. The force acting on the spindle is more constant, and the service life of the cutter is prolonged.

If there is a risk of cutter breakage, the computer will immediately reduce the amount of feed or stop the operation completely. Using our high-end computer processing customers, its processing efficiency has achieved amazing improvement. If the process is compatible, the processing time can be reduced by 10%. We have managed to cut the processing time by another half. When the number is large, it will free up a lot of machining capacity. ” In addition, this method is effective no matter whether Walter tool is used or not. It only needs to meet the system requirements of the machine tool.

The Goodway GS-6000 series gravity turning inserts turning center, available from Yama Seiki, combines a high-rigidity boxway bed with slot milling cutters large-diameter servo indexing turret and a two-step gear-spindle structure. Three models are available, with maximum turning lengths of 950, 1,980 and 3,300 mm (37.40", 77.95" and 129.92"). Multiple operations, including turning, milling, drilling and tapping, can be performed on a workpiece with available live tooling and C-axis capabilities.

The machine features a turret disk measuring more than 750 mm in diameter and a 45-degree slant bed with wide boxways. X- and Z-axis rapids are 787 and 944 ipm, respectively. According to Yama Seiki, the turning center provides 0.5-sec. indexing times from station to station and 1.5-sec. times for stations at 180 degrees. The two-speed headstock is driven by a 50-hp FANUC motor. Fully enclosed protection covers isolate chips and coolant inside the machine.

The Cemented Carbide Blog: tungsten long inserts

The Syncrono 2D laser cutting system BTA deep hole drilling inserts is available with Prima’s CV5000 laser resonator. Designed for high cutting speeds, the CV5000 increases productivity, cuts thicker materials and produces a quality cut with a reduced heat-affected zone, the company says.

The system features a special laser head that includes two additional linear-driven, parallel kinematic axes on the moving gantry, creating a “machine within a machine.” This allows the cutting head to cut at an acceleration ranging to 6 G. This enables the laser system to cut more than 1,000 holes per minute.

The system is available with a fully loaded material handling system consisting of a 10- or 15-shelf storage pallet loading/unloading unit; an automatic arm with pick-up device and suction cup loading; a double-sheet thickness control device; a sheet metal separation unit; a controller; and standard protection tungsten carbide inserts barriers. The continuously working system feeds production as it removes and stacks part. The addition of an automatic loading/unloading system can increase production, reduce manual labor and permit “lights-out” manufacturing. According to the company, its vibration-free design and a constant beam path through the 60″ × 120″ work area provide accurate, reliable cutting, even in small and intricate profiles.

?

Shops looking to reduce their tooling costs generally focus on the price they pay and the quantity of tools they buy. They evaluate lower-cost suppliers. They optimize cutting conditions so tools last longer.

However, too few of these shops pay attention to the moment of the purchase. Buying a tool at the wrong time can waste money, too.

For example, a shop loses money when it purchases tools too early. The combined cost of all of the tools in the shop that have been bought but not yet put to use—tools in toolboxes as well as tools in the crib—is the amount of money the shop has tied up in tooling instead of earning an investment return somewhere else.

A shop also loses money when it purchases tools too late. The machine that sits idle because an urgently needed tool is on order is another example of an investment producing no return.

And simply purchasing tools too readily is a third source of waste. In theory, no new tool should be used if an appropriate reground tool is available. But in practice, making sure used tooling gets reground is a housekeeping chore that is easy to overlook. Plus operators tend to use the new, virgin tooling even when reground tools are available.

The potential costs of these hidden expenses—carrying inventory, surprise downtime, underused regrinds—are generally on the rise. Newer high speed and multi-process machine tools are more productive, meaning the value of any work lost to downtime is that much higher. And with these machines cutting faster and cutting more difficult materials, they use expensive tools for a larger proportion of their work. Regrinding therefore delivers more of a savings, and the tool crib may come to represent a considerable glut of tied-up capital.

The Ponca City, Oklahoma, facility belonging to Smith Tool is one shop that illustrates these points. In fact, it would be hard to find a better illustration. Smith Tool is a maker of rock bits for the mining and petrochemical industries. Aggressive hard turning applications require the shop to use cubic boron nitride (CBN) tools and lots of them. The high purchase price of this tooling exaggerates all of the secondary costs that go unexamined in many shops. While scaling back on CBN was not an option, the company did find room to cut its tooling costs significantly by establishing more effective procedures for how it manages these expensive tools.

Rock bits are the cutting tools used to drill the earth, but these cutting tools have moving parts. Three interlocking studded wheels break up the rock and carry the fragments away. (See Figure 1, at right.) The working force on the bit—often tens of thousands of pounds—is concentrated on the hubs of these wheels.

Preventing these hubs from wearing quickly accounts for an important design feature. While the bits’ major components are made of hard steel, the wear surfaces are made of even harder steel. On each hub, a pocket is machined into the 120 degrees of circumference that faces down and bears the brunt of the force. A proprietary alloy of harder steel is then welded into this pocket. (See Figure 2.)

The resulting part presents a machining challenge. Turning the hub to size after the secondary material has been added makes for an interrupted cut, even when the cutting tool remains fully engaged. With each rotation, the cutter hits two distinctly different materials.

At the same time, the application is also a traditional interrupted cut. The turned diameters feature flats and holes that have to be machined in place before the turning occurs.

Smith Tool was an early convert to single-point hard turning. The company has been cutting these parts instead of grinding them for many years now. Lead times were longer when the parts were ground, because every new bit design required a new custom grinding wheel and dresser. By making the parts through CNC turning and avoiding the wheel and dresser altogether, the company now brings new bits to market in about three to four months less time.

The challenge was learning how to turn these parts. Ceramic—a common cutting tool material for hard turning—delivers inconsistent and unpredictable life in many of Smith Tool’s applications. The company uses more expensive CBN instead, and even at that, the shop has devoted considerable experimentation just to determine what parameters would let CBN cut many of its parts reliably. Aggressive cutting can cause the facility’s 13 CNC lathes to consume 500 CBN inserts in a week. Even with streamlined inventory, it’s not uncommon for the shop to have $250,000 in CBN on site at any given time.

Freeing up the productive capital associated with this inventory was one of the most important steps the company took to cut its tooling expenses. Relief came from a new arrangement with the shop’s CBN supplier, Mastertech Diamond Products of Mentor, Ohio. In essence, Mastertech opened a tiny, tiny branch office on Smith Tool’s shop floor.

That “branch office” is the tool dispensing machine shown in Figure 3. It qualifies as the tool supplier’s branch office because the supplier owns the machine and all of the cutting tools inside. Smith Tool is not required to pay for any CBN tool until a Smith employee draws it out of the machine.APKT Insert By letting the company hold on longer to the price of each of these tools, this seemingly simple procedural change improves the cost efficiency of Smith’s process.

The relationship between the company and its tool supplier requires flexibility on both sides. Tooling applications supervisor Ernie Buford, for example, is the Smith employee most directly involved with the tool dispensing machine and its inventory. But he also does work for Mastertech, spending an hour or so per week restocking the machine with replacement inserts that do not yet belong to Smith Tool. Replacement inserts are shipped almost on a daily basis and stored in a secured cabinet until Mr. Buford transfers them to the machine.

He says the hour each week is a price he is happy to pay for the savings he sees in his tool budget.

Operators U Drill Inserts obtain CBN tools from the machine using a bar code scanner. An operator scans his own badge, then scans barcodes posted on the machine to identify the job, machine tool and insert number. (See Figure 4.) Fundamental to the effectiveness of this system, says Mr. Buford, is the software that runs the machine and captures and organizes this information.

A software change recently improved that effectiveness. “Cribmaster” tool management software from WinWare (Marietta, Georgia) delivered some small efficiency gains. Mr. Buford now e-mails the automatically compiled tool-use reports required for restock and billings, where once he had to fax this information. He also physically restocks the machine more quickly because of the software’s ability to execute machine motions more efficiently.

But the software also delivered this more significant improvement: It let Smith Tool achieve a further reduction in its CBN costs by making better use of regrinds.

The software the shop used previously made no allowance for whether a tool was reground or new, so the shop assigned regrinds separate and distinct numbers. As a result, an operator was prone to use a new tool without realizing there was a comparable regrind in stock.

The new software avoids this waste by making a distinction between regrinds and new tools that share a common number. If a regrind is available for a given tool number, the software offers up the used tool first, before it will release a new one.

Smith Tool has built on this feature by establishing a system of its own to ensure dull tools are collected. A combination safe sits next to the tool dispensing machine. This safe has a slot cut in the top like a coin bank, and operators deposit their dull CBN there. (See Figure 5.) Every two weeks, the shop sends the safe’s contents back to the CBN supplier, who evaluates each insert’s potential for recycling.

The safe provides an easy, secure collection point for dull tools. Data collected in the WinWare software show its effectiveness. Since putting the safe in place, insert returns as a proportion of the inserts dispensed have risen from 56 percent to better than 99 percent. Every insert that is collected, reground and purchased again saves Smith Tool about one-half the cost of a new insert.

A combination safe and badges for access are the kinds of security measures a shop might put in place to guard against theft. But theft has never been a problem at the Ponca City facility. At issue instead, says Mr. Buford, is inventory control.

The security measures establish accountability. An employee’s accountability for any insert begins when he takes that tool from the machine, and it ends when he deposits the tool in the safe. Knowing exactly who has each tool, where it is being used, and how many tools are left in stock helps control Smith Tool’s costs in a variety of ways.

Much of the cost control comes from avoiding surprises. In the past, human oversight caused some insert use to go unrecorded. As a result, “we would think we have 100 inserts, then discover we had only 25,” Mr. Buford says. A machine could be idled or work could be delayed while a needed insert was quickly shipped. Automatic tracking, coupled with frequent reordering, overcomes this problem.

But Mr. Buford says improved tracking of tools also controls costs by directly improving the machining process.

On a recent report of CBN use, for example, Mr. Buford saw this clear and surprising trend: Out of three identical CNC lathes performing the same operation, one machine was wearing out tools at a considerably faster rate.

The shop’s maintenance personnel took a look at the machine and soon found the explanation. One toolholder was off center.

Under the shop’s less formal system for tracking tools, says Mr. Buford, this problem might have long gone undiscovered. But more formal collection of data made the problem immediately apparent. Thanks to better tool management, he observes, this shop reduced its consumption of costly CBN.