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Expanding the Vision to High-Mix Low-Volume Fab

By: Brad Kuvin

VIDEO: Automated Laser-Cutting Cell at Laystrom Manufacturing

Friday, February 01, 2013
 

From Friday night to Sunday night, nearly every week, when most metalforming facilities sit quietly idle, some 50,000 pounds of sheetmetal undergo processing at Laystrom Manufacturing. During one recent weekend, the Chicago firm processed 73,000 lb. of material lights-out, requiring only a short Saturday visit from an operator to restock its raw-materials storage tower.

Two 10-shelf storage towers flank a pair of 4000-W laser-cutting machines to comprise Laystrom Manufacturing’s 3800-sq.-ft. laser-production cell. Cell activity starts at the raw-material storage tower (top) and ends at the finished-goods tower (bottom), where fork-truck drivers remove cut sheets and direct material for further processing—primarily press-brake bending. Watch it run by visiting our online Multimedia Center at metalformingmagazine.com.
Enabling such unattended productivity is the firm’s main attraction, an automated laser-cutting cell. The cell stars two 4000-W cutting machines flanked by a 10-shelf raw-material storage tower at one end and a 10-shelf finished-goods storage tower at the opposite end. So while Laystrom has its roots firmly planted in hard-tooled metal stamping, and still provides stamped metal parts to a variety of customers, it’s the company’s investment in flexible fabrication equipment that’s enabled the successful transformation into the world of mass customization, according to president Bob Laystrom.

“When our stamping business started to dwindle in the late 1980s, we turned to fabrication and purchased our first turret-punch presses (in 1988) and laser-cutting machine (in 1998), a 2-kW Amada machine, to attract a new customer base,” Laystrom recalls. Describing the firm’s remarkable reinvention from stamper to fabricator, Laystrom adds: “Now, we don’t have to wait for stamping programs to go through multiple revisions…and perhaps never come to fruition. In fabrication, most of what we quote goes into production within 3 months, some within a few days of quoting.”

The business churns furiously at Laystrom, where dozens of new part numbers enter production every month. That’s a far cry from its stamping days, and requires a different mindset, all the way from the management suite to the production floor. Contributing mightily to that mindset shift was the firm’s acquisition, in 2006, of a local (Elk Grove Village, IL) sheetmetal fabricator. The human capital and expertise the company gained in that acquisition enabled Laystrom’s transformation from low-mix high-volume stamping to high-mix low-volume fabrication.

“The acquisition proved vital for us,” says Laystrom, “not so much for the capital equipment we acquired but rather for the talent that came to us.” Of the firm’s 60 employees, 10 came from the fab shop Laystrom acquired.

“Although we closed that Elk Grove Village facility,” Laystrom continues, “we brought over a team of engineers and production workers well-versed in this type of work. The acquisition allowed us to immediately get up to speed on CAD, purchasing and in production.”

The Automation Arithmetic

Laystrom is piloting a process to shift from product validation to process validation, by creating standard coupons (shown) of varying combinations of workpiece material types and thicknesses, and laser-cutting the coupons to develop acceptable cut quality. It then documents the process parameters so that when starting a new job, the machine operator will simply compare the part to the coupon, verify proper process settings—optics, cutting parameters and so on.
Following the talent influx of 2006-2007, Laystrom make a major revamp to the production floor. In 2008, the firm replaced its 1998-vintage laser-cutting machine with a new 4-kW machine (an Amada FO with shuttle table). Along with the machine came the material-handling automation system. Laystrom does the math:

“Lasers are expensive, around $500,000 each, and we spent another $500,000 on the automation. Without full-scale automation and only simple shuttle tables, we might get 80 hr. per week from each cutting machine, operating two shifts per day. With the automation, we’re processing material 140 to 150 hours per week on each cutting machine, while reducing overtime dramatically. Amortizing the automation investment over the useful life of the cutting machines makes the automation investment extremely inexpensive. And, if business slows, we can scale back or eliminate the second shift and still yield 140 hr. per machine per week while working one shift.”

Laystrom added to his automated laser cell in 2011 with the purchase of a second 4-kW machine, this one an Amada FOM2 machine with high-speed shuttle table. The FOM2, says Amada, boasts new features such as an eight-station automatic nozzle changer, water-assisted cutting and cut-process monitoring for automatic pierce detection—designed to minimize pierce time, particularly useful on thicker plate. This feature senses the instant that the laser beam pierces the material, and then immediately initiates the cutting process.

Three Years Make a Difference

The firm’s newest laser-cutting machine also features a downdraft dust- and fume extraction system (from Camfil Farr) located beneath the cutting table. It’s divided into four sections, and during the cutting process, only the ducts directly beneath the cutting head are open for fume extraction. The ducts in the other sections remain closed to improve dust collection and reduce energy consumption. Amada also says that the machine’s state-of-the-art resonator and optics system increases cutting speed and quality over previous models, which Laystrom can attest to.

“With the new machine we’ve seen a 5- to 7-percent increase in effective speed, or output and productivity, compared to the 2008 model,” Laystrom says. “Most of that improvement comes from increased control over the piercing process. And, the new machine also does a better job on reflective materials like stainless steel and aluminum. For example, a job that features numerous pierces and takes 2 hr. to process on the 2008-vintage machine might only require 80 min. to process on the newer model. So, we tend to schedule that type of work on the new machine.”

Most (70 percent) of the material that runs through Laystrom’s laser-production cell, and moves onto a series of press brakes for forming, comprises carbon steel. And some 30 percent of that work winds up in assemblies for the firm’s largest customer, an OEM manufacturer of agricultural machinery. Stainless-steel sheet represents another 15 percent of the work load, much of it for the power-distribution industry.

“This (stainless steel) is where the piercing capabilities of the FOM2 really pays off,” says Laystrom. “We can laser-cut holes in stainless-steel panels rather than having to process the work on a turret press, and avoid the extra material-handling operations. In fact, with the new laser we’ve been able to decommission three of our four turret-punch presses.”

Laystrom’s fabrication department processes material from 0.030 to ¼ in. thick, with plenty falling within 0.030 in. to 14 gauge. Sheet size has grown as the firm has replaced its original 1998-vintage laser (48 by 48 in. sheet capacity) to a maximum of 60 by 120 in. In addition to supplying the agricultural market, Laystrom has a sizable customer base for precision stamped and fabricated parts in the medical and telecommunications industries—each comprises 20 percent of its workload.

Attacking the Cost of Quality

When we visited the firm, Laystrom’s brother Jim was busy developing a new process-validation methodology to help the firm minimize its cost of quality. “We’re piloting a process to shift from product validation to process validation,” says engineering manager Jim Laystrom. “To get started, we’re creating standard coupons of varying combinations of workpiece material types and thicknesses, and laser-cutting the coupons to develop acceptable cut quality, then documenting the process 4 third-, and fourth-run parts orders that have gone through the laser one time will not require first-part inspection from our quality-control department. Instead, the machine operator will simply compare the part to the coupon, verify proper process settings —optics, cutting parameters and so on —and he’ll be good to go. This will dramatically decrease our quality costs and increase machine run time.”

Also impacting quality has been the firm’s dedication to maintaining the integrity of the cutting bed, an egg-crate-style bed comprised of V-cut slats of sheetmetal. “As the slats wear from use, the workpiece material may move out of level, which can impact cut-edge quality,” says manufacturing engineer Terry Foley. “So we ask our operators to keep a close eye on the condition of the cutting-machine beds and change out the slats—which we cut ourselves—regularly. This is particularly important when working with thinner work. And, when jobs run lights-out, any quality issues caused by out-of-level work will compound sheet after sheet. We certainly don’t want a quality issue to persist through an entire untended shift.”

Lastly, cut-edge quality took a turn for the better when, in 2008, the firm committed to using nitrogen assist gas, rather than oxygen, on any work thicker than 11 gauge. “Nitrogen cuts faster and improves edge quality to help avoid deburring and improve paint adhesion,” says laser technician Hugo Vega. “We’ve been taking on more stainless-steel work and heavier-gauge mild steel,” adds manufacturing manager Eric Hauser.

Laystrom’s fabrication department processes material from 0.030 to ¼ in. thick, with plenty falling within 0.030 in. to 14 gauge. With its newest laser-cutting machine, purchased in 2011, it’s experienced a 5- to 7-percent increase in effective speed, or output and productivity, compared to its 2008-vintage laser-cutting machine. “Most of that improvement comes from increased control over the piercing process,” Laystrom says.

To support its nitrogen habit, Laystrom purchased two Amada EZ Cut nitrogen-generating systems. Compared to using bottled nitrogen, according to Amada, using generated nitrogen (95 percent pure) will provide a more polished finish on thin-gauge stainless steel.

Finally, Hauser notes that some customers in the medical and power-distribution industry have been requesting laser cutting with 99-percent pure nitrogen. To meet that need, Laystrom recently installed a bulk system for distributing ultra-high-purity nitrogen. “It allows us to bulk-fill units directly from the delivery truck,” says Hauser, “and gives us the equivalent of three dewars manifolded together. This increases our ability to run lights-out and maintain the gas pressure required.”

A Symphonic-Like Cell

Watching the automated laser-production cell run is like watching a carefully directed symphony. Each cell component relies on the other components, and the entire orchestra of parts relies on the conductor—the operator (and also the programmer) to carefully direct its activities. Featured is the Amada AMS 3015 system; Amada says that more than half of its customers that have purchased the system have added a second laser, as has Laystrom. The modular building-block system includes the raw-material and finished-sheet storage towers, and shuttle tables for carrying material to and from each laser-cutting machine. Each tower shelf is rated to 4400 lb. of material and a maximum stacking height of just under 5 in. “And, down the road we can increase capacity by adding another five shelves to the material tower,” says Bob Laystrom.

The goal when programming the cell, explains second-shift supervisor Sergio Cano, is to try to have one cutting machine running jobs with longer cycle times, and load shorter-running jobs on the second cutting machine, to “minimally disrupt the material-handling automation,” says Cano. “But then we may have days where one laser runs from the automation all day while the operator loads smaller blanks on the second machine, to process small orders.”

Most often, the workcell processes a fully loaded tower of raw material over two shifts. The operator will start his day by spending 2 hr. loading the material-storage shelves to capacity, and initiating the programmed run cycle from the cell scheduling controller. “We probably run 50 different types and thicknesses of carbon steel, stainless steel and aluminum regularly,” adds Vega.

The software (Amada’s Dr. Abe) then takes over. It tracks inbound material inventory, and also keeps tabs on where each job ends up in the finished-goods tower. “And we can monitor the entire cell over the Internet via computer or smart phone,” adds Foley.

With so much laser-cutting capacity, pressure to keep production flowing falls on downstream press-brake bending, and to react Laystrom has beefed up operations there, particularly on second shift. “Up until we bought the second laser-cutting machine,” continues Foley, “we’d run 45 hr. per week on regular 9-hr. days for one shift, and stretch to 10- or 11-hr. days on overtime. Plus Saturdays. Now we have a second shift and need two or three additional press-brake operators to keep the work moving.” MF

 

See also: Amada North America, Inc, Camfil Air Pollution Control

Related Enterprise Zones: Automation, Fabrication


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