Integrated automation of turning centers can be the solution to meeting production schedules and profit goals.
Courtesy of Fuji Machine
The hand-held Fuji MAX SP1 robot controller provides an interface between the operator, automation and machine.
Need a turning center operator but are hesitant to hire an additional worker? An integrated robot and associated automation equipment might just be the ticket for optimizing a part manufacturer’s turning, as well as drilling and milling, operations by keeping the spindles operating as much as possible.
Turned parts typically have short cycle times of 1 to 3 minutes, requiring an operator to be constantly opening and closing the machine’s door to load and unload parts, according to Ron Ehrmann, sales manager for Automation Solutions Inc., West Chester, Pa., a distributor of machine tools and automation equipment. “There’s a lot of hands-on time where he’s totally dedicated to that one machine,” he said. “He can’t do anything else, and then when he’s not there, that machine is not running.”
To overcome that situation, Automation Solutions offers the “Lean Machine” system from Ellison Technologies, which includes a Fanuc M10 robot with riser, robot controller, drawer unit and fencing. End users usually start with four drawers with a 150-lb. capacity for each drawer and a 20 "×20 " usable envelope with 6 " of spacing between drawers. The robot accesses a drawer by pulling it to itself, and drawers, which are manually loaded, can also be accessed from outside the cell.
In operation, the robot pulls a drawer out to pick up a part, feeds the machine and then places the finished part in a container or back in the drawer. “When you do have a repeat job, even if it’s for 25 pieces, it’s easy to load it up,” Ehrmann said. “You just pull the drawer out, load your parts, push it back in and the robot takes over from there.”
Ehrmann noted that the system starts at around $75,000 and can include a vision system, which costs $3,000 to $6,000, if parts require special orientation. Typically, users of Lean Machine cells have achieved a payback period of 2 years or less using the system on a one-shift basis.
The system sits on a metal skid so it can be moved to another location if needed. Although companies that machine various quantities of a host of different parts often feel automation equipment isn’t suitable for their operations, Ehrmann noted that job shops make good use of Lean Machine projects. “You have all these drawers, so you can have very small part runs, and you do your automation setups during machining time,” he said.
Automation Solutions primarily adds automated drawer systems to existing equipment because shops aren’t operating the vast majority of their machines at full capacity.
Automating New
On the other hand, machine tool builder Amada Machine Tools America Inc. (formerly Amada Wasino America Inc.), Rolling Meadows, Ill., integrates the majority of its automation equipment with new machines. That’s partly because the comparative cost of the automation integrated into a new machine is substantially less than buying it and having it retrofitted, according to George Kowalewski, the company’s national sales manager.
Amada builds various automated turning centers, including 2-axis, gang-tool machines; 2-axis, single-spindle turret machines; 3-axis, twin-spindle lathes with live tooling; and 4-axis mill/turn machines available in single-spindle, single-turret and twin-spindle, twin-turret models. “The common thread throughout all of our products is the gantry loader,” he said, adding that the exception is the Mi8 machine, which uses a Fanuc LR Mate loader, a 5-axis robot.
Courtesy of Amada Machine Tools America
Amada’s twin-spindle, twin-gantry JJ3 turn/mill machine simplifies automatic measurement, according to the company.
The 2-axis gantry loader uses Fanuc servomotors to control both programmable axes. “Because it’s an encoder-driven system, we can stop anywhere along the travel of our gantry loader and perform all sorts of operations, namely gaging,” Kowalewski said. Gaging to measure parts and to adjust for tool wear is often critical in an automated turning environment because scrap is created quickly when machining is not monitored.
He noted that 65 percent of Amada’s business is with automotive operations, which typically run 240 days a year, 22-plus hours a day. “They expect 95 percent machine availability time.”
Nonetheless, the equipment is suitable for turning shorter runs because the end-of-arm tooling, or gripper jaws, can be quickly removed, and the gripper jaws locate accurately through a key/keyway system with a keyhole-type arrangement for the socketed cap screws, according to Kowalewski. “By breaking loose a fastener and rotating it three times without having to remove the fastener, you’re able to slip the jaw up and off the key/keyway arrangement and replace it,” he said.
Kowalewski added that the Amada carousel-type part supply device is also quick-change. “We are demonstrating a complete part changeover in less than 15 minutes in our Schaumburg [Ill.] Solutions Center,” he said.
Not only are automated turning centers appropriate for small part runs, but they can also handle small parts. Amada has one Illinois customer that found it challenging for a human operator to hold and get the tiny workpieces into and out of the workholders without dropping them. “It was tedious and, with all that repetitive motion, they were concerned about operators developing carpal tunnel syndrome,” Kowalewski said. “We were able to put together bowl feeders with our automation equipment to pick up blanks and drop off finished parts.”
Courtesy of Automation Solutions
The “Lean Machine” system from Ellison Technologies and Automation Solutions includes a Fanuc M10 robot with riser, robot controller, drawer unit and fencing.
Vertical Turning
Sometimes turning center automation doesn’t involve a robot. That’s the case with EMAG’s inverted spindle design, which is an integrated, self-loading turning machine concept where end users do not need robotic handling devices, according to Peter Loetzner, CEO of machine tool builder EMAG LLC USA, Farmington Hills, Mich. “The core feature is the pick-up spindle, which travels outside of the machining area, picks up the part, brings it inside, does all the machining and unloads it all by itself,” he explained.
The inverted spindle is on EMAG’s VSC, SLC and VL series vertical pickup turning machines. Loetzner added that all moving automation parts and accessories are outside the cutting area and on top of the machine, which helps keep the machine envelope clean and maintenance free.
An end user could add a robot with a camera to take parts out of a bin and load them into the automation equipment, but if the parts are manually loaded into the carrier prisms, then the end user doesn’t require accessory robots or any other external components, Loetzner noted. In addition, the universal carrier prism design allows the machine to accept a range of parts without any changeover requirements or fixturing or palletizing of parts, according to Loetzner. If needed, inexpensive pilot pins or pallets of a simple design can also be used as a standard automation solution.
One-Stop Shop
For machine shops that produce different products and must frequently change processes, it is helpful for automated turning to be modular, in that it can be reconfigured, retooled and reset for those different products. That’s the case with turning center automation provided by Fuji Machine America Corp., according to Bill Gore, regional sales manager for the Vernon Hills, Ill., machine tool builder. In addition to the machine, which includes the integrated robot, many peripheral devices, such as conveyance systems, work stoppers, workholding and auto gaging, are available. They are all designed and manufactured by Fuji, Gore noted.
Courtesy of EMAG
EMAG’s recirculating, prism-type loading frames—the carrier prisms—take components to and from the pickup station and require no resetting. They accommodate workpieces with different sizes, shapes and diameters.
He emphasized that the Fuji MAX SP1 robot controller, which provides an interface between the operator, automation and machine, is separate from the Fanuc CNC for controlling toolpaths. Slaving off of the CNC limits the number of inputs and outputs an end user can use when adding peripheral devices in the future. “Using these two integrated controllers is a more efficient way to automate equipment,” Gore said. “You have the available inputs and outputs to handshake and communicate with that automated device that’s receiving your part. You can expand.”
How a robot loads a workpiece into a turning center is also an important consideration. Gore noted that a Fuji 4-axis-controlled swing arm robot provides more freedom to create a flexible manufacturing solution. The loader loads a workpiece underarm similar to how a human operator would. “We’re not lifting up over the chuck, dripping and leaving chips and swarf on key contact points,” he said, adding that the robot is conveying the part in front of the operator at eye level to avoid obstructing his view of the operation.
Although Fuji Machine serves the high-volume automotive industry, Gore emphasized that the company also serves eight-man job shops. “They need to automate to stay competitive,” he said.
Reduced Labor
In addition to being able to accurately plan how many parts are going to be produced each day, shops benefit by being able to minimize or eliminate human labor and, potentially, the number of machine tools required with automated turning centers. Loetzner recalled one customer replacing four machines with one EMAG automated machine and calculated payback based on cutting the number of shift operators from 10 to three. After 3 months, however, the customer called to indicate his labor assumptions were incorrect. “I asked ‘what happened?’ and he said he was able to run the shift with two people,” Loetzner said, adding that payback will take 6 months. “Half a year is aggressive, but always within a year.”
He added that some customers operate equipment without operators for lights-out machining. “Operator intervention is rarely required.”
For the workers who remain, automation can enhance the lathe operating experience. Rather than manning one machine and performing the same tasks ad nauseam, an operator runs multiple machines and conducts varied functions. “It’s not uncommon for end users to have one operator running three, four, five machines. Tasks then change from taking parts in and out of the chuck and hitting cycle start to attending the part supply, placing finished product, doing inspection and those types of activities,” Amada’s Kowalewski said. “The operator-to-spindle ratio really decreases when you go to automation.” CTE
About the Author: Alan Richter is editor of Cutting Tool Engineering, having joined the publication in 2000. Contact him at (847) 714-0175 or alanr@jwr.com.
10 common mistakes when purchasing automation
Buying a piece of automation can be a long and difficult process. Presented here are the 10 most common mistakes made when purchasing automation equipment.
1. No equipment specification. Failure to define your company’s expectations with regards to performance, aesthetics and hardware preferences will eventually lead to confusion and misunderstanding. A simple equipment specification could include the following:
• Performance expectations, such as cycle time, yield, quality expectations and machine or system uptime.
• Preferred hardware list, such as programmable logic controller, valves and robots. Let your automation/integration partner know if you have preferred component suppliers.
• Design requirements, such as guarding, wiring and plumbing requirements, as well as any in-plant obstacles or floor space constraints.
• Product information, including prints and current process information.
• Acceptance criteria, detailing what your expectations are before you’ll take delivery.
2. Failure to visit prospective automation houses before the quoting process begins. Requests for quotation are often sent to an automation house with little prior knowledge about the company. A visit to one or more suppliers early in the process helps assure you are looking at viable solutions from capable partners.
3. Incorrectly estimating the cost. Most know a manager who has presented his supervisor a proposal for an automation project, sold the idea and grossly underestimated project cost. To save face, the manager and his subordinates spend their time looking for the right price rather than the right solution. It’s better to get a quote before presenting your idea to the money men.
4. Not enough technical capability in-house to support the machine. Companies often purchase a piece of automation without considering the technical expertise required to maintain it. Be sure to consider all the costs associated with new and unfamiliar technology.
5. Failure to involve the production people. The people responsible for ultimately operating a piece of automation can make it look good or bad. Allow the production people to be involved with the project early on, giving them an active role and a chance to take ownership.
6. Poor communication with the automation vendor. Even after a detailed equipment specification has been submitted to the vendor, constant constructive communication must be maintained. Simply documenting conversations and responding to written correspondence for the sake of maintaining good records is not enough. Your company and chosen vendor must form a team.
7. Accepting automation equipment from the vendor before it is ready. Allowing this usually prevents the automation from performing according to plan and damages the vendor/company relationship. Re-engineering and troubleshooting after installation are the biggest source of project cost overruns.
8. Failure to supply the vendor with up-to-date drawings and parts within specification. This causes expensive delays. Even the best automation houses don’t always detect nonconformance from the parts to the prints until it is too late, making rework inevitable.
9. Failure to design for automation. Some products cannot be manufactured or assembled automatically. Some process components cannot be fed automatically, and depending on how frequently your product mix changes, it might not be cost effective to produce the part automatically. When automation is difficult, a semiautomatic or even manual solution may be more feasible.
10. Using the wrong technology for an application. Failure of a project engineer to do his homework may result in the least efficient use of equipment, especially if it’s not purchased as part of a long-term strategy.
—Automation Solutions
Contributors
Amada Machine Tools America Inc.
(847) 797-8700
www.amadawasino.com
Automation Solutions Inc.
(610) 430-3670
www.asi-pa.com
EMAG LLC USA
(248) 477-7440
www.emag.com
Fuji Machine America Corp.
(847) 821-7137
www.fujiamerica.com
Related Glossary Terms
- 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.
- chuck
chuck
Workholding device that affixes to a mill, lathe or drill-press spindle. It holds a tool or workpiece by one end, allowing it to be rotated. May also be fitted to the machine table to hold a workpiece. Two or more adjustable jaws actually hold the tool or part. May be actuated manually, pneumatically, hydraulically or electrically. See collet.
- 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.
- gang cutting ( milling)
gang cutting ( milling)
Machining with several cutters mounted on a single arbor, generally for simultaneous cutting.
- lathe
lathe
Turning machine capable of sawing, milling, grinding, gear-cutting, drilling, reaming, boring, threading, facing, chamfering, grooving, knurling, spinning, parting, necking, taper-cutting, and cam- and eccentric-cutting, as well as step- and straight-turning. Comes in a variety of forms, ranging from manual to semiautomatic to fully automatic, with major types being engine lathes, turning and contouring lathes, turret lathes and numerical-control lathes. The engine lathe consists of a headstock and spindle, tailstock, bed, carriage (complete with apron) and cross slides. Features include gear- (speed) and feed-selector levers, toolpost, compound rest, lead screw and reversing lead screw, threading dial and rapid-traverse lever. Special lathe types include through-the-spindle, camshaft and crankshaft, brake drum and rotor, spinning and gun-barrel machines. Toolroom and bench lathes are used for precision work; the former for tool-and-die work and similar tasks, the latter for small workpieces (instruments, watches), normally without a power feed. Models are typically designated according to their “swing,” or the largest-diameter workpiece that can be rotated; bed length, or the distance between centers; and horsepower generated. See turning machine.
- milling
milling
Machining operation in which metal or other material is removed by applying power to a rotating cutter. In vertical milling, the cutting tool is mounted vertically on the spindle. In horizontal milling, the cutting tool is mounted horizontally, either directly on the spindle or on an arbor. Horizontal milling is further broken down into conventional milling, where the cutter rotates opposite the direction of feed, or “up” into the workpiece; and climb milling, where the cutter rotates in the direction of feed, or “down” into the workpiece. Milling operations include plane or surface milling, endmilling, facemilling, angle milling, form milling and profiling.
- swarf
swarf
Metal fines and grinding wheel particles generated during grinding.
- turning
turning
Workpiece is held in a chuck, mounted on a face plate or secured between centers and rotated while a cutting tool, normally a single-point tool, is fed into it along its periphery or across its end or face. Takes the form of straight turning (cutting along the periphery of the workpiece); taper turning (creating a taper); step turning (turning different-size diameters on the same work); chamfering (beveling an edge or shoulder); facing (cutting on an end); turning threads (usually external but can be internal); roughing (high-volume metal removal); and finishing (final light cuts). Performed on lathes, turning centers, chucking machines, automatic screw machines and similar machines.
- turning machine
turning machine
Any machine that rotates a workpiece while feeding a cutting tool into it. See lathe.
- vision system
vision system
System in which information is extracted from visual sensors to allow machines to react to changes in the manufacturing process.