robotic blow

The Robotic SUBTA systems have also created unexpected improvements in the manufacturing process. The company noted a net reduction of 1/2 percent of scrap, adding 500,000 bottles per year to its output simply by virtue of not dropping the bottles. Since fewer products need to be reground, the company also saves money considering the cost to run the regrind machines has gone up greatly as the cost of oil increases. In addition, this reliable process has cut the employee bending movements by 50 percent.
Compared to a different take out system, six axis robots give us an option to even pack the bottle or bring it to a leak detection machine. Now we have dwell time at the robot,” said the plant manager. “Six axis robots give us the ability to look at secondary operations and an opportunity to potentially add some value to our customer’s process. We can present it to our customers as a benefit. Efficiency at the facility has been greatly affected by the addition of Robotic SUBTA units.

Motion Controls Robotics’ created the Robotic SUBTA system, a pre-engineered robotic system designed for PET blow-molded bottle handling. The system uses different robotic units depending on the type of machine that is being unloaded. The Robotic SUBTA system grabs and sets the bottles on a conveyor, standing up, acting as a takeaway unit. The system provides increased throughput due to high reliability and uptime and cycle times faster than most mold machine rates. The Robotic SUBTA system also requires a minimum of floor space, a high priced commodity in a manufacturing facility.

The plastics manufacturer also considered a vendor with a fixed automation system that included a simple slide but decided that system wasn’t reliable enough for its needs. In addition, every time the mold tooling changed, the slide also had to be changed to accommodate the new product. This created a higher cost to change tooling that was not acceptable. The facility included one machine with a manufacturers fixed automation system, but they wanted to find a more flexible and reliable solution.
Everything in the plant runs much more smoothly. More bottles are being produced, but the pace seems slower since there was a reduction in complexity in the system,” said the plant manager. “We have seen a reduction in the commotion and activity since employees can now work at a constant pace and succeed without as much physical effort. We also have a greater chance to understand the bottlenecks in the manufacturing process. We are reviewing to see where we can make an economic justification for adding automation,” said the plant manager. “We chose the ones that are simple to execute first that run one mold all day, as well as the systems with the highest stress strain or ergonomic safety issues. We are looking for future automation as soon as we can.
About the Author: Robert Lamb spent his childhood reading books and staring into the woods — first in Newfoundland, Canada and then in rural Tennessee. There was also a long stretch in which he was terrified of alien abduction. He earned a degree in creative writing. He taught high school and then attended journalism school. He wrote for the smallest of small-town newspapers before finally becoming a full-time science writer and podcaster. He’s currently a senior writer at HowStuffWorks and has co-hosted the science podcast Stuff to Blow Your Mind since its inception in 2010. In his spare time, he enjoys traveling with his wife Bonnie, discussing dinosaurs with his son Bastian and crafting the occasional work of fiction.

It combines the automatic feeder with the automatically moving electric screwdriver to realize the complementary supply of screws and the locking, which greatly improves the production efficiency and saves manpower. Once the screwdriver is lifted after locking the screw, the automatic feeder will send the other screw to the Escape of the automatic feeder. The screwdriver head absorbs the screw and the robot can automatically move according to the coordinate point and tighten it. This is particularly suitable for multi-station workpieces of the same specification. 
A national manufacturer of stock and custom plastic packaging solutions for the food packaging, chemical, automotive and household industries faced the challenge of improving its safety and ergonomics associated with its manual system of unloading its Nissei Bottle Making Machine at its manufacturing facility. The company also wanted to find a solution to reduce scrap and increase productivity.
The company contacted Motion Controls Robotics to ask them to help develop a solution that would automate its bottle take out process and alleviate its safety and ergonomic issues due to repetitive stress injuries. They also wanted to create a solution that would reduce scrap, which ultimately would help increase sales without having to produce more product than it did in the past.

About the Author: Robert Lamb spent his childhood reading books and staring into the woods — first in Newfoundland, Canada and then in rural Tennessee. There was also a long stretch in which he was terrified of alien abduction. He earned a degree in creative writing. He taught high school and then attended journalism school. He wrote for the smallest of small-town newspapers before finally becoming a full-time science writer and podcaster. He’s currently a senior writer at HowStuffWorks and has co-hosted the science podcast Stuff to Blow Your Mind since its inception in 2010. In his spare time, he enjoys traveling with his wife Bonnie, discussing dinosaurs with his son Bastian and crafting the occasional work of fiction.
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