Using additive manufacturing (AM), Sandvik Coromant Uses AM To Create Lightweight Milling Cutter CoroMill 390, a lightweight milling cutter that helps minimise vibration and improve security during machining with long overhang.
“When designing our new lightweight CoroMill 390, material has been tactically removed to create the optimal cutter design for minimising mass,” explained Magnus Engdahl, product application manager at Sandvik Coromant. “This is called topological optimisation and it makes the cutter more compact and significantly lighter than a conventional version, thus helping machine shops to boost the productivity of their long-overhang milling operations. Moreover, a shorter distance between the damper in the adaptor and the cutting edge improves performance and process security.”
The Sandvik Coromant CoroMill 390 can perform long-reach face milling, deep shoulder and side milling, cavity milling, and slot milling. The tool is available in 40mm (arbor 16 coupling) and 50mm (arbor 22 coupling) diameter variants. Three or four inserts (size 11) can be specified to suit the application, and differential pitch and internal coolant are provided on all cutters.
With an advanced solution that enables manufacturing companies to take steps towards digital machining and Industry 4.0, Sandvik Coromant has introduced connectivity capability to its series of Silent Tools tool holders. The innovation is offered as part of the company’s CoroPlus suite of connected solutions for machine shops keen to embrace the rapidly advancing trend of industry digitalisation.
Among a number of enhancements, the latest Silent Tools technology for internal turning at long overhangs now feature embedded connectivity within the adaptor. Named Silent Tools Plus, this solution enables data from the machining process to be collected and sent to a dashboard, giving the operator a valuable insight into what is happening inside slender tubular components. For instance, it will be possible to detect if there is too much vibration or if the surface quality is at risk of being compromised. Furthermore, operators will be able to reduce the time that the machine runs without the tool in cut.
“The combination of CoroPlus connectivity and Silent Tools damping technology makes this a solution that shows the technical heights we can expect from the machining solutions of the future,” said Åke Axner, Product Manager Silent Tools Turning Adaptors at Sandvik Coromant. “Silent Tools Plus turning adaptors with embedded connectivity support our overall CoroPlus strategy, which enables customers to work more efficiently.”
By way of example, the Silent Tools Plus vibration indicator is able to detect issues with machining at an early stage, helping to prevent vibration-associated issues such as noise, poor surface quality and accelerated tool wear. Furthermore, centre height setting functionality displays the level of the cutting edge, so that it can be quickly and easily set according to requirements. The result is better machining performance and longer tool life.
The range of Silent Tools from Sandvik Coromant is designed to minimise vibration through a pre-tuned dampener inside the tool body that consists of a heavy mass supported by rubber spring elements. The benefits of this design are multi-faceted, allowing machine shops to increase metal removal rates, improve surface finish, secure the process or reduce production costs.
The Silent Tools Plus turning adaptor also includes a new Wedge Lock quick-change interface between the adaptor and cutting head. The fast and accurate cutting head changes this facilitates will appeal to manufacturers in a variety of industries, including aerospace, for machining components such as landing gear components, and in oil and gas, where the machining of long tubular parts is commonplace.
In order to boost the first stage roughing operation on newly cast aluminium parts for the automotive industry, Sandvik Coromant is introducing its M5Q90 angential milling cutter. Designed to complete “cubing” (first machining of faces after casting) in a single operation without creating burrs, the new tool is fitted with PCD tangential inserts that provide a smooth and stable cutting action to lower power consumption and eliminate vibration. This concept ensures reliable performance, improved tool life, exceptional surface finish, high metal removal rate and an increased number of parts per insert.
“To enhance efficiency, our new M5Q90 tangential milling cutter features fully engineered cutter bodies matched with dedicated PCD insert geometries that feature a positive cutting angle to reduce cutting force and load on the machined component,” explained Emmanuel David, Global Automotive Product Manager at Sandvik Coromant. “The inserts, which are easy to handle and adjust, offer reduced cost per part along with high accuracy and repeatability.”, added Jacques Gasthuys, Global Automotive Application Engineer.
M5Q90 cutter bodies are designed according to customer specifications and hence meet the requirements of high-productivity machining – the tool can operate in high-speed conditions in excess of 20,000 rpm. However, all cutter bodies offer the same design of tip seat, coolant channel, lead angle and rake angle. Inserts are always kept in stock.
If desired, the cutter body tool life can be further extended in engineered solutions with PCD inserts protected by rows of carbide inserts, a configuration that also serves to increase the depth of cut capability. While the basic tool with PCD inserts offers 2-4 mm (0.079-0.157 inch) depth of cut in full engagement, this can be boosted to in excess of 4 mm (0.157 inch) using the engineered solution with protective rows of carbide inserts.
Aluminium cylinder heads and engine blocks will be among the principal components to benefit, typically at automotive foundries or Tier 1/Tier 2 suppliers. By way of example, the cubing operation on a cast cylinder head would involve machining the camshaft face, inlet/outlet face and combustion face. Typical cutting data using M5Q90 might include a speed of 2500 m/min (8202 ft/min) and feed per teeth of 0.20 mm (0.008 inch). Users also benefit from high-precision coolant channels that provide the option for either emulsion or MQL application.
The M5Q90 completes the Sandvik Coromant offer for machining aluminium automotive parts, complementing the M5B90, M5C90, M5F90, CoroMill® Century/590 and M5R90 tooling solutions.
Capable of both face and shoulder milling, the M5Q90 is also suitable for many applications in the general engineering and aerospace sectors.
The recent arrival of all-directional turning and tools has re-written the conventional rules of this age-old machining process, offering tantalising improvements in productivity. By Håkan Ericksson, general turning product manager, Sandvik Coromant
One of the manufacturing megatrends of recent decades is to simplify and minimise the number of machining set-ups required to produce a specific Y-Axis component. Contributed by Sandvik Coromant
Markets call for shorter lead times and reduced inventories, and this creates a clear incentive for original equipment manufacturers (OEMs) and perhaps even more so for their suppliers to look for ways to streamline component production as much as possible.
Complex geometries must be accomplished with a minimal number of set-ups and operations, preferably in a Y-Axis single machine. The profitability of a given part may even depend on the capability of combining several set-ups in a single machine.
Machine Tools Upgraded With Live Tooling And Y-Axis
One aspect of the single set-up trend is adding “live tooling”, in other word rotating tools, to turning centres. To accomplish this, Y-axis turn-mill machines were introduced in the late 1990s. The initial idea was to simply make it possible to drive a milling cutter, drill or threading tap on one or more tool positions in the turret to eliminate limitations of polar interpolation and the related programming difficulties.
The first simple types of live tools in turning centres had a significant limitation, however. Because the rotating cutters were in most machine designs simply added to the turret, they could only be driven in the same two axes of motion as the turning tools, in other words on the X- and Z-axes.
As a result of this, any workpiece feature that is not parallel or perpendicular to the spindle centre line or is located along the workpiece centre line, was not within the direct reach of the rotating drill, mill or tap driven by the turret.
To improve the reach, an extra set of ways was added to move the live tool across the spindle face. This was accomplished by mounting the live tools on revolver sides or on its face, by installing the Y-axis ways on a slanted bed, or by using an independent milling head.
Both machine tool makers and manufacturers soon recognised the benefits of this approach. Now, around two decades later, the Y-axis has become a standard feature in nearly all multi-task machines and optional in many new turning centres.
Adding the Y-axis into a turning centre provides 90-degrees angularity between the three linear axes, in a way much like a 3-axis machining centre, as the Z-axis customarily is parallel to the spindle centreline in most lathe-type machine tools. While the X-axis provides the conventional plunge turning feed motion, the Y-axis creates a vertical dimension perpendicular to the plane jointly defined by the Z- and X-axes.
Challenges When Parting Off
Parting off is a crucial stage in any turning process where it is required. It takes up only a small percentage of the total cutting time but it is usually the last operation before the part is finished.
A breakage of the parting tool can easily result in machine downtime and quality issues, and in a worst-case scenario the workpiece may have to be scrapped and all the value added during previous work stages is lost. Due to this, manufacturers are reluctant to compromise in any way the process security of a parting operation.
Material cost is another major factor. Particularly when working costly materials, such as heat- resistant super-alloys (HRSA), there is a strong incentive to use the narrowest possible inserts.
These factors result in two diametrically opposite requirements for parting tools: They should be as narrow and slender as possible to minimise the loss of material and to optimise the reach of the tool for maximal work diameters.
Yet slender tools easily suffer from poor stability and consequently from vibrations and noise. Surface finish and dimensional tolerances ruined by chattering are generally unacceptable risks in parting operations.
While the Y-axis substantially broadened the possibilities to use rotating tools in multi-task machines and turning centres, now this capability has inspired a innovation in one of the original missions of these machine tool types: Y-axis parting. This new parting-off tool and method offers significant productivity and process security improvements in potentially any parting operation.
Conceived from Sandvik Coromant, Y-axis parting is based on an simple principle. While conventional parting off tools align with the X-axis of the machine tool, the Y-axis tool has simply been rotated 90 degrees anti-clockwise to align with the Y-axis.
In the conventional parting tool configuration, the relatively long and slender cutting blade and holder is fed at a 90 degree angle into the rotating workpiece and the largest cutting force is generated by the cutting speed, and the rest by feed motion.
The resultant force vector is directed diagonally into the tool at an angle of roughly 30 degrees, in other words across its second weakest section (only the width of the blade is weaker). This is conventionally counteracted by reducing the blade overhang and by increasing the blade height. The downside of both remedies is potentially compromised usability of the tool.
By turning the tip seat 90 degrees and utilising the Y-axis, the tool can cut its way into the workpiece essentially with its front end, which nearly aligns the resulting cutting force vector with the longitudinal axis of the blade.
The finite element method analyses carried out by the company’s research and development team found that the distribution of forces eliminates critical stresses typical to conventional blades and increases the bending stiffness at a maximum cutting depth (CDX) of 60 mm by more than six times. Or, conversely, the susceptibility to plastic deformations and instability is as low as one sixth in the Y-axis design compared with the deformations typical to conventional parting blades.
Benefits Of Y-Axis Parting
The more than 600 percent increase in blade stiffness allows substantially higher feed rates and longer overhangs without a loss in stability, which consequently improves the productivity of the tool in equal measure.
Thanks to this, parts can be parted off closer to the subspindle to save raw material and improve the stability of the operation. Rather than the rigidity of the parting blade and tool holder, it is the insert that now represents the bottleneck for increasing performance of parting operations.
The general recommendation for parting off bars is to minimise overhang (OH) or, at a long OH, to use a light cutting geometry or to reduce feed. A common threshold value for reduced feed is an OH exceeding 1.5 times blade height. With Y-axis tooling, longer overhangs can be achieved without settling for less than optimal feed rates, cutting geometries or tool dimensions.
As in all turning operations, it is important to position the cutting edge of a parting tool as close to the workpiece centre line as possible to avoid pip formation or tool breakage. Parting tools should be set within ±0.1 mm of the workpiece centreline.
The conventional recommendation for long overhangs is to set the cutting edge 0.1 mm above centre to compensate for bending down. Thanks to the increased stiffness and consequently reduced bending, Y-axis tooling may eliminate the need for over-centre settings and prevent the related disadvantages such as premature insert breakages when pushing through centre and rapid flank wear.
Measuring the tool length calls for particular care, because when it comes to Y-axis tools, the length also determines the centre height. On the other hand, this can be seen as a security feature against set-up errors: because measuring the length is always necessary, it also serves as a double-check for the centre height setting. If the cutting edge is difficult to see, there is also a gauge plane on the end of the tool. The distance between the gauge plane and the cutting edge is marked on the Y-axis tools.
Other benefits include lower noise levels, better surface finish and a more reliable process as well as the capability to part off larger diameters than currently possible.
Machine-Specific Aspects Of Y-Axis Parting
Turning centres are generally used for mass production from bar stock, typically 65 mm in diameter, and in this type of machining the biggest benefits of Y-axis parting are improved productivity and surface quality. The opportunities for quality optimisation can also be interesting, since parting off is typically the last stage for a component. An additional opportunity is to improve the machining economics by reducing the parting width.
For multi-task machines, Y-axis parting blades primarily offers increased accessibility and capability for larger diameters. A pre-test saw a 50 percent increase in the overhang when cutting a conventional 120 mm diameter bar at the maximum feed capacity of the insert. A 300 percent productivity increase was achieved with no process security complications. In a customer test case, Y-axis parting successfully replaced band sawing for a 180mm diameter Inconel bar, resulting in significant productivity improvement thanks to dramatically shorter machining times.
In a typical slant-bed machine, the X-axis creates an ‘uphill’ slanted towards the front of the machine, with spindles on one or both side ends of the slant bed, and the X-axis travel is usually substantially longer than the Y-axis travel. The resulting work space limitations must be considered when considering the usability of Y-axis parting for a specific component.
In a multi-task machine, which essentially could be characterised as a machining centre with turning option, typical tool assemblies, such as the HSK63T blade adaptor, are often relatively long to enable sufficient reach between the main chuck and sub-chuck. As a result of this, the total set-up is weak in the X direction compared to the Y-axis load, where the cutting force is directed into the tool assembly and into the machine spindle.
Similar conditions apply to many turning centres equipped with a driven tool/milling option on the Y-axis. Typical Y-axis tool assemblies, usually based on a VDI adaptor or a bolt-on blade adaptor for the machine-adapted clamping unit are long and slender to reach between main- and sub-chuck and allow parting off close to chuck. Again, the result is a weak set-up in the X-direction compared to Y-axis, where the cutting force is directed into the tool assembly and into the turret. Y-axis parting can help to eliminate both problems.
How To Get Started
An investment in Y-axis parting is first and foremost a change in the approach to parting operations and the related ways of working. It offers a way to more fully utilise the capabilities of machines already fitted with a Y-axis. Alternatively, it is an option that can substantially increase the productivity of parting operations in a new machine or a modified process set-up.
The biggest concrete investment is in programming, with obvious implications in terms of personnel resources and scheduling. The tool motion itself is easily programmed, while different machines and control system have different parameter settings that must be changed to get constant cutting speed on the Y-axis. Necessary parameter settings are described in the CNC control manual.
Y-axis parting can even offer a chance to reduce the tool inventory because there is less need for dedicated blades and since the new Y-axis blades fit in standard adaptors and use standard inserts such as CoroCut QD.
As a practical consideration, it should be noted that the cutting edge is 7 mm above the Y = 0 position when mounted on a standard blade adaptor. The operator should make sure that this protrusion is offset in the CNC program.
Sandvik Coromant Inserts and grades has introduced the GC4305, an insert for steel turning to maximise metal removal rates, shorten processing times and enable good component quality. Sandvik machining offers high cutting data, an ability to withstand high temperatures, and has a wear-resistant Inveio coating to achieve long tool life.
The Sandvik Coromant insert GC4305 can also be used for dry machining and Sandvik Coromant GC4305 insert offers cost savings with its aforementioned properties, as well as with the elimination of the need for cooling lubricants and associated wastes, and cheaper disposal of chips.
The vibration damper from Sandvik Coromant helps to maintain stable production during deep hole machining operations. Using the machine control adjustment unit, the device allows operators to step away from the machine and manage process modification without hand tools or the risk of personal injury.
The vibration damper offers bi-directional functionality, ensuring it can be deployed for both push and pull applications. In addition, there is a self-locking unit in the event of a power loss.
The next stage in the metalworking production journey is to monitor and share with other interested parties precisely what is happening in the machining process. By Adir Zonta, product manager process monitoring and machining analytics, Sandvik Coromant
Stockholm, Sweden: Sandvik Materials Technology has announced its intention to sell its welding and stainless wire operations to further consolidate its product portfolio and improve its long term performance.