Improved holemaking efficiency drives powertrain machining throughput.
Courtesy of Chrysler Group
A typical automotive engine—in this case Chrysler’s Hemi V-8—requires hundreds of holes of all types, produced using drilling, reaming, boring and tapping.
Learn more about deep-hole machining
For more information on deep-hole machining, view a video presentation here.
“In automotive powertrain machining, the OEMs and their suppliers are striving for balanced processing—cycle times that are more or less the same for each process. That’s why holemaking can become a bottleneck or require more than one machine to meet throughput requirements.”
That’s how Jun Ni, professor of mechanical engineering, University of Michigan, Ann Arbor, sums up the potential problems facing manufacturers of engine and transmission components.
The good news, according to Ni, is throughput when machining engine blocks and other major powertrain components can be improved by 20 to 25 percent simply by optimizing holemaking tools and processes. Ni is also the director of the university’s S.M. Wu Center for Manufacturing Research, which conducts basic and applied research in machine tools and machining, among other topics. He has more than 20 years of experience working with the Big Three and other automotive OEMs on machining optimization.
On one project, Ni worked with a Japanese automaker to improve throughput when single-tube gundrilling oil holes in crankshafts. “They were using four stations to make those holes, and if any of those stations went down they had a backlog,” he said.
By changing cutting parameters and drill geometry, the company was able to maintain the same production level with three machines, enabling the fourth to be used if another machine was down.
Courtesy of Kennametal
Optimized for drilling of cast irons, Kennametal’s YPC drills use a three-margin design and other features to reportedly improve roundness, straightness and cylindricity.
He cited another project from a few years ago that aimed to drill a 9mm-dia., 1 "-thick A-319 cast aluminum alloy in 0.15 seconds. “This was work for a consortium of the Big Three and Caterpillar,” Ni recalled. “Spindle speed was 20,000 rpm, and, at that speed, the operation was more like punching than drilling.”
Ni noted that the project required comprehensive analysis and redesign of the holemaking process, including tool material, flute and point design, tool coating and coolant delivery. “We had to look at the tool cross section,” he said. “Torsional strength was important, but so were chip evacuation and point design. The point geometry had to produce very small chips that could be easily and quickly flushed out.” A couple cutting tool suppliers eventually adopted elements of the twist drill design, he added.
Research Drivers
Driving the emphasis on holemaking productivity in powertrain components are the sheer numbers of holes involved, the switch at OEMs from dedicated transfer lines to more flexible CNC equipment and evolving powertrain materials, according to Ni.
“Automotive powertrain components require hundreds of holes, so holemaking accounts for a disproportionate percentage of tooling costs, machining time and total cycle time consumed, and scrap/rework costs,” he said.
Courtesy of Walter
Walter reports that its Titex XD drills can run up to 10 times faster than gundrills and eliminate pecking when drilling holes up to 70 diameters deep.
Swapping a dedicated transfer machine that can drill multiple holes simultaneously for a single CNC spindle also creates a throughput challenge that can be solved only by adding capital equipment or by faster hole production, Ni added. “You may need to drill 15 or 20 times faster with a CNC machine to get the same hole production as a transfer line drilling station.”
In terms of materials, twin emphases on weight reduction and improved engine efficiency are resulting in use of stronger materials that are more difficult to machine, according to Patrick Nehls, product manager for Walter USA LLC, Waukesha, Wis.
“An example is compacted graphite cast iron, which is so tough that an engine with a CGI block can actually be lighter than an engine with an aluminum block of the same displacement,” Nehls said. “CGI engine blocks can have much thinner cross sections than aluminum blocks.”
Compared to gray iron, CGI is 75 percent stronger and up to 75 percent stiffer. Audi, BMW, Jaguar and Hyundai were early users of CGI in automotive engines, and nearly all NASCAR teams have CGI engine blocks or blocks with CGI liners.
According to Nehls, Walter does significant internal and external testing to determine what types of holemaking tools are needed to help users continue productivity improvements. He described results of one test at the University of Darmstadt, Germany, that involved drilling 7mm-dia., 10 "-deep oil line holes. “We ran at about 200 sfm, 21.5 ipm in CGI, and tool life was 175 holes, or roughly 138 ' of drilled holes.”
Courtesy of Seco Tools
An example of a special tool from Seco is this long-length reamer for finishing of camshaft bores.
Deep-hole drilling also requires a piloting strategy. “In our case, the pilot drill is sized just a few microns larger in diameter than the long drill, so you’re essentially going into a clearance hole for about the first 1.5 to 2 diameters of depth,” Nehls said. “That’s done so the long drill isn’t cutting at first, which will produce excessive wear and chatter.”
For holes up to 70 diameters deep, Walter reports that its Titex XD drills can run up to 10 times faster than gundrills and eliminate pecking. “Very often at that kind of aspect ratio you’re looking at gundrilling, but a gundrill has a relatively low penetration rate,” Nehls said. “The XD drills can run faster because they have two effective cutting lips, which enable us to basically go twice as fast.”
The through-coolant tools don’t require high-pressure coolant, he added. They are available in diameters from 0.197 " to 0.472 ", and can be specified with a tip coating for either soft steels or cast irons.
Optimized for Iron
For holemaking in cast iron, solid-carbide YPC drills from Kennametal Inc., Latrobe, Pa., use a three-margin design to minimize drill “walking” when entering the work material and improve hole straightness. Automotive powertrain applications for the cutting tools include drilling differential and planetary gear carriers and housings, engine blocks and manifolds.
The tools feature the company’s “Y-Technology,” which uses three margins and creates predictable, unbalanced motions offset by a counterbalance effect. The result is good hole quality in terms of roundness, straightness and cylindricity, according to Chris Merlin, global team leader, holemaking for the toolmaker. “The YPC drill gives greater cylindricity, especially in deeper holes, which have a tendency to ‘run’ because of the grain structure of cast iron. That not only improves quality of as-drilled holes, it has the potential to improve tool performance in secondary tapping operations,” he said.
“In one test—using a 13mm-dia. YPC drill and a competitor’s drill to produce 45mm-deep holes in GG25 gray cast iron—our drill ran at basically twice the speed and achieved identical tool life,” Merlin added.
Courtesy of Seco Tools
Efficient valve seat machining requires a combination tool that can finish the valve guide and the seat angle quickly and precisely. Such tools often combine a carbide reamer for the guide and PCD tool for the seat.
Process parameters for the Kennametal drill (with the competitor’s in parentheses) were: spindle speed of 4,897 rpm (2,448), cutting speed of 200 m/min. (100), feed rate of 0.35 mm/rev. (0.25) and surface speed of 1,714 mm/min. (612). “Of course, it does require machine tools that are able to run at the speeds the tool needs without excessive vibration or other issues,” Merlin said.
Kennametal is producing standard YPC tools for drilling 3, 5 and 8 diameters deep.
More on Specials
With all the various types of holes—very deep through-holes, blind-holes, cross-holes and so on—required for automotive powertrain components, special tools are often required to achieve the necessary quality and productivity.
“Very often we can take a standard technology but adapt it into a special tool,” Nehls said. “It’s common to provide dozens of special tools on, for example, an engine block. For one project, we had 25 different special drills on an engine block producing something like 7 million holes per year.”
For Seco Tools Inc., Troy, Mich., specials also include increasingly popular combination tools, according to Mike Smith, product manager, reaming and toolholding. “At both the OEMs and in the Tiers, they are using a lot of combo tools to produce multiple features simultaneously, improve quality and reduce cycle time,” Smith said. “That holds true in both reaming and drilling applications.”
He added that the toolmaker focuses a lot on specific parts. “We try to optimize holemaking for the component the shop is working with, whether it’s a cylinder head or another drivetrain component,” Smith said.
Smith cited valve-seat reaming as an example of an application where a combination tool is particularly applicable. “If you can hit multiple angles on the valve seat with a single tool, that saves a lot of time,” he said.
A combination tool for valve seat reaming might use a traditional carbide reamer to produce the valve guide and a PCD insert to produce the angle on the seat, which must be precise to ensure maximum fuel efficiency. “Seco has two different setups to do that kind of work, depending on whether the shop is running a transfer line or a CNC machine,” Smith said. “On a transfer line, the reamer is actually fed out from the head. For flexible cells that use CNC machines, there’s another style. Both are very effective.”
Regardless of whether the shop is using dedicated or flexible equipment, the numbers of components required for automotive powertrain applications are so massive that a short time reduction is significant. “Those fractions of a second add up to minutes, hours and days over the course of a year,” Smith said. “And, of course, time is money.” Just one component—the cylinder head—accounts for more than 50 percent of the tool cost for engine machining, he added.
Seco also does a lot of work in transmitting power from the engine through the transmission and out to the wheels. Here again, combination tooling can reduce cycle time and improve quality. According to Thomas Sandrud, drilling product manager for the toolmaker, a Seco PerfoMax combination drill is being applied to produce a 0.866 "-deep hole, a chamfer and a back chamfer in gray cast iron wheel hubs in a single operation. The through-coolant insertable tool, which circular interpolates a back chamfer on the exit hole and eliminates deburring, runs at 525 sfm with a feed rate of 0.006 ipr. “Tool life is approximately 100 ' per cutting edge,” Sandrud said.
Low-carbon steel half shafts require shallow holes, and Seco’s Crownloc system comes in stub lengths as short as 1.5 times diameter. “The shorter the drill you can use, the more accurate the hole geometry you can hold, the better positioning you get and the more reliable the process will be,” Sandrud explained. “In one case, we switched a customer to the Crownloc drill at 1.5 times diameter and increased tool life due to increased stability.”
Seco’s Crownloc tools are available with geometries optimized for ISO P, M and K materials, Sandrud noted, and both the crown and the drill body are standard products.
Perhaps nowhere is productive holemaking more important than in automotive powertrain applications. The sheer numbers of holes and throughput rates required make it a challenge, but it’s one that machine and cutting tool suppliers are up to. CTE
About the Author: Jim Destefani, senior editor for CTE, has written extensively about various manufacturing technologies. Contact him at (734) 528-9717 or by e-mail at jimd@jwr.com.
Courtesy of Mazak
Penske Engines machines cylinder heads complete using a special fixture on a Mazak multitask machine.
Courtesy of Mazak
Each cylinder head requires about 50 small holes, which are produced using through-coolant carbide tools and high-pressure coolant.
Holemaking at Penske Racing
In the world of NASCAR, you might think quality would be a more important consideration than machining throughput. And, you’d be right—to a point.
“Quality trumps machining speed in our business,” said Scott Corriher, president of Penske Engines, Concord, N.C. “But efficiency is also a consideration.” Machining throughput is important because the shop builds about 250 engines per NASCAR season, for both Penske Racing teams in the Sprint Cup, the company’s Nationwide series team and a few specials working with Dodge.
Penske uses a Mazak Integrex e410 multitask machine for cylinder head machining and Mazak machining centers for engine block production, according to Rick Huneycutt, machine shop supervisor. “For cylinder heads, we produce maybe 50 small holes using Kennametal tooling on the multitask machine,” he said. “That includes drilling and tapping of a lot of mounting holes to attach the head to the block using through-coolant tools and high-pressure coolant.”
The team receives engine blocks from Dodge with oil holes and other high-aspect ratio holes already machined, so complex holemaking on blocks is limited to some boring, Huneycutt added.
Engine production starts when the shop receives block, cylinder head and intake manifold castings from Dodge. “If things go well, we might get 10 to 12 races out of an engine block,” Corriher said. “We might get three races out of a cylinder head, and we can run intake manifolds pretty much indefinitely.”
Machining is what brings the castings to life, enabling a typical Sprint Cup engine to produce 840 to 850 hp. “Each race team has its own designs, and a lot of freedom within the rules to control, for example, where port openings are located in the head,” Corriher said.
Precision machining also can lead to improved fuel mileage—something that paid off big for Penske Racing at Kansas Motor Speedway in early June, when driver Brad Keselowski was able to execute a fuel-saving strategy in the closing stages to take victory. The race stayed caution-free and the team squeezed 57 laps on the 1.5-mile track out of its final tank of fuel. “We try to balance the design on intake manifolds and cylinder heads to get the best balance of fuel efficiency and power,” Corriher said.
Both men expect the flexibility of the shop’s Mazak equipment to help Penske Engines gear up for its next big challenge—NASCAR’s move from carburetors to fuel injection for the 2012 season. “Our work with Dodge is a two-way street, and this is going to be a big change,” Corriher said. “But we’re confident we’ll be ready.”
—J. Destefani
Contributors
Kennametal Inc.
(800) 446-7738
www.kennametal.com
Mazak Corp.
(859) 342-1700
www.mazakusa.com
Penske Engines
(704) 788-8996
www.penskeracing.com
Seco Tools Inc.
(248) 528-5200
www.secotools.com
University of Michigan S.M. Wu Manufacturing Research Center
(734) 936-0363
www.wumrc.engin.umich.edu/index.html
Walter USA LLC
(800) 945-5554
www.walter-tools.com/us
Related Glossary Terms
- arbor
arbor
Shaft used for rotary support in machining applications. In grinding, the spindle for mounting the wheel; in milling and other cutting operations, the shaft for mounting the cutter.
- boring
boring
Enlarging a hole that already has been drilled or cored. Generally, it is an operation of truing the previously drilled hole with a single-point, lathe-type tool. Boring is essentially internal turning, in that usually a single-point cutting tool forms the internal shape. Some tools are available with two cutting edges to balance cutting forces.
- cast irons
cast irons
Cast ferrous alloys containing carbon in excess of solubility in austenite that exists in the alloy at the eutectic temperature. Cast irons include gray cast iron, white cast iron, malleable cast iron and ductile, or nodular, cast iron. The word “cast” is often left out.
- centers
centers
Cone-shaped pins that support a workpiece by one or two ends during machining. The centers fit into holes drilled in the workpiece ends. Centers that turn with the workpiece are called “live” centers; those that do not are called “dead” centers.
- chatter
chatter
Condition of vibration involving the machine, workpiece and cutting tool. Once this condition arises, it is often self-sustaining until the problem is corrected. Chatter can be identified when lines or grooves appear at regular intervals in the workpiece. These lines or grooves are caused by the teeth of the cutter as they vibrate in and out of the workpiece and their spacing depends on the frequency of vibration.
- clearance
clearance
Space provided behind a tool’s land or relief to prevent rubbing and subsequent premature deterioration of the tool. See land; relief.
- computer numerical control ( CNC)
computer numerical control ( CNC)
Microprocessor-based controller dedicated to a machine tool that permits the creation or modification of parts. Programmed numerical control activates the machine’s servos and spindle drives and controls the various machining operations. See DNC, direct numerical control; NC, numerical control.
- coolant
coolant
Fluid that reduces temperature buildup at the tool/workpiece interface during machining. Normally takes the form of a liquid such as soluble or chemical mixtures (semisynthetic, synthetic) but can be pressurized air or other gas. Because of water’s ability to absorb great quantities of heat, it is widely used as a coolant and vehicle for various cutting compounds, with the water-to-compound ratio varying with the machining task. See cutting fluid; semisynthetic cutting fluid; soluble-oil cutting fluid; synthetic cutting fluid.
- cutting speed
cutting speed
Tangential velocity on the surface of the tool or workpiece at the cutting interface. The formula for cutting speed (sfm) is tool diameter 5 0.26 5 spindle speed (rpm). The formula for feed per tooth (fpt) is table feed (ipm)/number of flutes/spindle speed (rpm). The formula for spindle speed (rpm) is cutting speed (sfm) 5 3.82/tool diameter. The formula for table feed (ipm) is feed per tooth (ftp) 5 number of tool flutes 5 spindle speed (rpm).
- feed
feed
Rate of change of position of the tool as a whole, relative to the workpiece while cutting.
- fixture
fixture
Device, often made in-house, that holds a specific workpiece. See jig; modular fixturing.
- gundrill
gundrill
Self-guided drill for producing deep holes with good accuracy and fine surface finish. Has coolant passages that deliver coolant to the tool/workpiece interface at high pressure.
- gundrilling
gundrilling
Drilling process using a self-guiding tool to produce deep, precise holes. High-pressure coolant is fed to the cutting area, usually through the gundrill’s shank.
- inches per minute ( ipm)
inches per minute ( ipm)
Value that refers to how far the workpiece or cutter advances linearly in 1 minute, defined as: ipm = ipt 5 number of effective teeth 5 rpm. Also known as the table feed or machine feed.
- polycrystalline diamond ( PCD)
polycrystalline diamond ( PCD)
Cutting tool material consisting of natural or synthetic diamond crystals bonded together under high pressure at elevated temperatures. PCD is available as a tip brazed to a carbide insert carrier. Used for machining nonferrous alloys and nonmetallic materials at high cutting speeds.
- precision machining ( precision measurement)
precision machining ( precision measurement)
Machining and measuring to exacting standards. Four basic considerations are: dimensions, or geometrical characteristics such as lengths, angles and diameters of which the sizes are numerically specified; limits, or the maximum and minimum sizes permissible for a specified dimension; tolerances, or the total permissible variations in size; and allowances, or the prescribed differences in dimensions between mating parts.
- reamer
reamer
Rotating cutting tool used to enlarge a drilled hole to size. Normally removes only a small amount of stock. The workpiece supports the multiple-edge cutting tool. Also for contouring an existing hole.
- tapping
tapping
Machining operation in which a tap, with teeth on its periphery, cuts internal threads in a predrilled hole having a smaller diameter than the tap diameter. Threads are formed by a combined rotary and axial-relative motion between tap and workpiece. See tap.
- twist drill
twist drill
Most common type of drill, having two or more cutting edges, and having helical grooves adjacent thereto for the passage of chips and for admitting coolant to the cutting edges. Twist drills are used either for originating holes or for enlarging existing holes. Standard twist drills come in fractional sizes from 1¼16" to 11¼2", wire-gage sizes from 1 to 80, letter sizes A to Z and metric sizes.