The fact that a fully-configured arc welding robot can be purchased for significantly less than an experienced welder makes in a year is pretty impressive. Of course, the price of robot itself is only part of the cost of setting up an automated welding cell. Also, automation imposes a whole new set of constraints on a manufacturing process, the consequences of which may not immediately be obvious.
For example, when I worked as a process engineer in highly-automated foundry, I came up with a way to reconfigure a mold which made four castings per pour so that it could make six castings per pour. This was a big deal - the number of pieces per mold was directly related to profitability, and this was a 50% increase! It would have represented over $1 million per year in increased profit.
The only problem was that I couldn't get six castings to fit into one of the totes which was used to carry the parts to the automated finishing cell. (Actually, I figured out a way to get them to fit, as long as they were loaded a certain way. But the way the process was set up required them to be randomly dumped into the tote. Loading them in an ordered way would have required an additional robot).
With human beings, this would be no problem - just train the operator how to load the parts, or else just tell him to put three of the parts in one tote, and three of the parts in another tote. But the automated system was set up such that one mold worth of parts had to go in a single tote! Re-writing the code to allow parts from a single mold to be split up between two totes turned out to be such a daunting task that none of the automation engineers - who were extremely talented guys, some of whom have since gone on to start their own company - was even willing to touch it.
Still, with the price of robots coming down, and increasingly user-friendly interfaces, it looks like automation will be making its way into more small-to-medium sized manufacturers.
You make an interesting point, Ann, when you mention that robot solutions may work for smaller shops. I would guess that means the overall cost of ownership is less. It sounds like it is less not necessarily because the robot is less expensive but because the software is less difficult from a user point of view. Does that mean that set-up is easier? It also sound like the new software doesn't require the programming that previous software required. Is that it?
It's interesting to see how advance robots, better pick-and-place systems, and improved cameras (machine vision) and camera interfaces are together working in concert to improve reliability on the production line. This is not a trend that's getting a lot of publicity, but when you go and visit plants, they're clearly getting good ROI on this stuff.
I agree with Alex that many of these production floor advances are not getting the "air time" that they should. Couple the improved automation systems with tighter integration with enterprise software platforms like PLM and MES and you have a recipe for manufacturers to get tighter controls, better visibility, and wring more efficiencies out of their production systems.
There is no doubt that automation delivers tremendous advantages to shops who employ it. My point is simply that automation brings with it a whole new set of manufacturing challenges. Is it worth it? Sure. But you are going to have to operate within the constraints imposed by the automated system, many of which you won't anticipate beforehand, no matter how hard you try. And if you have smart and innovative process engineers, they will constantly be going up against these constraints and trying to figure out how to "break" them in order to get even more out of the system.
Rob, you're exactly right, the overall COO is lower. Not only does the entire package cost less, including the robot itself, but the software gives engineers two options: program it yourself in an IDE or use the much easier point-and-click type interface for configuration and setup.
Dave, I, too, was surprised to hear that the robot costs less than an experienced welder. Of course, it still doesn't do everything an experienced welder can do. And, as you point out so clearly, the complexities of the automation process can get in the way of designing a better system.
Pretty cool, Ann. That whole point-and-click figuration and set-up is becoming more popular through the automation world. It's part of the whole plant-as-a-video game trend. Smart devices has helped the effort, and now apparently robots become an easier set up as well. This approach certainly keeps costs down.
This is a great development, and it should wind up making automating even short production runs economical. Programming these robots will wind up being the one thing that is a cost item. I have done robot programming in the manual mode, which is an intensely exacting process. Moving to each position with the required precision is quite tedious. Model based robot programming is a whole different realm, from what I understand. But it would seem that it may be better setting up a welding path on an actual part.
Many of the new adhesives we're featuring in this slideshow are for use in automotive and other transportation applications. The rest of these new products are for a wide variety of applications including aviation, aerospace, electrical motors, electronics, industrial, and semiconductors.
A Columbia University team working on molecular-scale nano-robots with moving parts has run into wear-and-tear issues. They've become the first team to observe in detail and quantify this process, and are devising coping strategies by observing how living cells prevent aging.
Many of the new materials on display at MD&M West were developed to be strong, tough replacements for metal parts in different kinds of medical equipment: IV poles, connectors for medical devices, medical device trays, and torque-applying instruments for orthopedic surgery. Others are made for close contact with patients.
New sensor technology integrates sensors, traces, and electronics into a smart fabric for wearables that measures more dimensions -- force, location, size, twist, bend, stretch, and motion -- and displays data in 3D maps.
As we saw on the show floor this week at the Pacific Design & Manufacturing and co-located events in Anaheim, Calif., 3D printing is contributing to distributed manufacturing and being reinvented by engineers for their own needs. Meanwhile, new fasteners are appearing for wearable consumer and medical devices and Baxter Robot has another software upgrade.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies. You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived. So if you can't attend live, attend at your convenience.