Robotic assembly Lines
This week’s post is presented by Acieta, a robotics integration and automation company with facilities in Wisconsin and Iowa. This article lists some of the advances that have made the use of robots common in various manufacturing areas.
Robots On The Assembly Line
Dispensing a bead of glue is a tricky task, the hand wobbles, speed changes and bead shape varies. Achieving the same result each time is impossible, humans have incredible capabilities but perfect consistency isn’t one of them. Precision assembly and dealing with components almost too small to see is incredibly difficult — these situations call for robotic assembly.
Using Robots for Automated Assembly
Growing numbers of manufacturers are adopting robotic assembly. Companies in the automotive industry see robotic assembly as a way to improve quality and safety, add flexibility, and address employee turnover and skills shortages.
The consumer electronics industry adds another benefit to this list: with increasing miniaturization only robots have the precision required for assembly work. Other industry sectors are adopting robotic assembly, too. Lawn equipment, domestic appliances and medical device manufacturing are all starting to reap the benefits.
Product Lifecycles and Capital Investment
In industries like electronics, product lifecycles are measured in months rather than years. This makes it difficult to justify investment in dedicated assembly equipment. In contrast, robots are highly flexible and quickly reconfigured for a new application. This reduces capital investment risk and can lower overall costs.
The automotive industry also utilizes robotic automation in a second way; whereas a body-in-white assembly line could only produce a single vehicle, using robots for assembly, spot welding, laser welding, brazing and polishing means multiple body styles can be assembled on a single line — one after another.
Robots aren’t new, so it’s fair to ask what’s changed to enable the growth in assembly line applications. The answer is sensor technology; both machine vision and force sensing. These technologies have matured, becoming easier and cheaper to use. As a result, many robot assembly applications now utilize one or both.
Similar to human eyes, vision systems locate parts in the robot’s working envelope — allowing the controller to accommodate variation in part placement by modifying programmed coordinates. Currently, most applications are 2-D — however 3-D vision, using stereo cameras, laser triangulation or pattern projection, is becoming popular.
What’s more, force sensing helps replicate how people put things together. A shaft might be pushed into a bore until resistance is encountered. The operator or robot then changes the insertion angle or rotates the shaft, sensing resistance and adjusting until the piece goes home.