The Zimmer Group uses FAULHABER electric motors in its new GEP2000 gripper series, which can often be found in laboratory automation.

The test tube needs to go into the centrifuge, the component at its correction position and the package onto the conveyor belt: gripping objects and placing them someplace else is a fundamental mechanical action in most work processes. In modern systems pick-and-place is performed by automated grippers. They must operate powerfully and delicately millions of times over. Increasingly, the necessary power comes from electric motors, such as the BX4 from FAULHABER. The Zimmer Group uses it for its GEP2000 gripper series, which can often be found in laboratory automation.

Testing and vaccination have proven to be effective against coronavirus, providing a way out of lockdown. But the pandemic also revealed the limits of what is possible. With the exponential spread of the virus, demand exploded – first for PCR laboratory tests, then for rapid tests, and later for vaccines. Capacity was inadequate every step of the way, and for many, the wait for test kits and vaccines seemed endless.

Laboratory automation against Covid-19  The pharmaceutical industry, medical technology, and medical laboratories worked quickly. This also applies to the expansion of production and to the increase of testing capabilities. A key factor in this success is automation. In laboratories, the pandemic proved to be a major impetus for automation. Automatic laboratory devices and universal, flexible robots can relieve specialists of work and increase throughput and efficiency. The automatic gripping and handling of samples, pipettes, or reagents is among the central, constantly recurring process steps here. For this purpose, delicate, industrial small parts grippers are required. Two technologies are generally available for gripping, explains Product Manager Maik Decker, who is responsible for this area at the southwest German manufacturer Zimmer Group. "Up until now, most grippers in industry have been powered pneumatically, i.e., with compressed air,” says Decker. “This technology is, however, not suitable for the hygienic environments required in laboratories, in medicine and in the pharmaceutical and medical technology industries. Grippers with electric drive are therefore used in these areas." 

Electric motor makes grippers flexible  In addition to the hygienic aspect, these grippers have another advantage: they function without a compressed air system and the associated lines. In some industrial sectors, these are standard equipment in production facilities because the machines in which the grippers are installed operate with electric power, and an electrical connection is much easier to install than a compressed air supply. The control of electric components is simpler and more flexible than working with pneumatics. "We see a clear trend toward the electric drive, not least in the automotive industry," Decker explains. 

New products from the Zimmer Group, such as the GEP2000 series, serve and consolidate this trend. The small parts gripper can hold components weighing up to 5kg as well as delicate parts such as test tubes. "The advantages of the electric drive also include the ability to adapt the gripping force to various objects at any time," explains Volker Kimmig, team leader for software at the Zimmer Group. "With the appropriate controller, the gripper can switch between different parts during a running process." 

10 million cycles without maintenance  The power for these work steps is supplied by a brushless DC-servomotor of the BX4 series from FAULHABER. In addition to a high torque, the strengths of the four-pole drive include its low vibration and noise, compact design, and a long service life. "We guarantee that this product will perform over 10 million cycles without maintenance," Kimmig says.

Such a motor must also provide additional features to meet the demands of continuous operation in a typical pick-and-place application. The development engineer uses the production of car keys as an example. "Large quantities and high throughput set the tone here. The gripper robots work under very high-paced, permanent stress with short cycle times. The motor must therefore start and then stop again at very short intervals. Decisive here is the motor's acceleration, as every tenth of a second counts in the process as a whole,” says Kimmig. “Moreover, the motor needs to be able to efficiently dissipate the heat that forms in such an operation in order to eliminate the possibility of overheating." 

The gripper experts from the Zimmer Group knew the BX4 from FAULHABER would satisfy these requirements. They had previously installed motors of this series in their GEH6000 gripper family. Essentially, this gripper works the same way as the small parts gripper. Its stroke, or the distance between the open and closed position of the gripper jaws, is significantly larger and can be up to 80mm. 

"The device can thus cover a wider range of different-sized target objects in the same process," Decker explains. "The smaller GEP2000, on the other hand, can also perform its work in very confined conditions. Of course, this only functions with a motor that delivers very high power in a very small space." 

Mechanical self-locking  The gripper series have one special feature in common with other Zimmer Group products. The motor power is transferred to the jaws by a worm gear drive with a steep pitch. Even in the event of a power failure, the gripping force is retained, and the respective position held. Once gripped, a work piece is held securely without an additional device such as a brake. 

The drive electronics in the two gripper types operate slightly differently. With the GEH6000, the encoder signals of the drive are used for positioning the jaws. With the GEP2000, this task is performed with the help of a positioning sensor. Both solutions achieve a high degree of repeatability: the specified path of the jaws is reproduced to within one five hundredths. 

"In many applications, the prepositioning when lowering the gripper to the target object is very important," Kimmig explains. "In constrained spaces, the open position is often only allowed to be very slightly larger than the closed position. When maneuvering a robot arm in a complex environment, it may also be necessary to make very precise pre settings. We do this using very precise electromechanics, where the motor once again plays a crucial role, as well as with a flexible data connection. Our devices can be equipped with IO-Link and with digital I/O. This makes it easy for them to move in and back out again just about everywhere." 

How to use proof-of-concept systems to make sure your automation system works.

About the presentation As the title suggests, this basic question is a common concern from many groups that are responsible for the implementation of automated systems based around some use of grinding or sanding, or polishing/buffing processes. While some of these groups already have existing automation in their plants, they’re expanding the roles of automation and going beyond the low hanging fruit, into some more challenging processes and methods. When going into this uncomfortable realm, it’s important to surround yourself with support from partner organizations that have the same vision. This is where the proof-of-concept system in the abrasive process solutions robot system is critical. The use of a tool such as the APS Lab, allows for customers and automation system integrators to try different approaches to solve processing challenges, and see those results before an end-use customer must commit to a design, method, or various hardware choices. Our presentation at the IMTS 2022 Conference will focus on helping end users and automation system integrators find a low cost/no cost avenue to create proof of concept processes and methods they need to confidently move their operations from manual to automation, or from outdated automation to current up-to-date automated systems.

Meet your presenters Mike Shappell was the manufacturing manager for Schlage Lock in Colorado, Delta Faucet (GAMCO Prod), SUNSPRING America, and Schaffner Manufacturing, before joining Norton/Saint-Gobain abrasives. Shappell has more than 40 years of experience as an end user of automation on the factory floor. He joined the Norton Abrasives team to focus on helping other end users.

Nathan Jackson is a graduate of Worcester Polytechnic Institute with an emphasis on robotic engineering. He is a graduate of FANUC Programming School for FANUC Industrial robots.

Tory Landes graduated from Tarleton University in Stephenville, Texas. She has more than 25 years of experience within the Norton/Saint-Gobain organization. She helps end users find better processes and automation to improve overall performance

About the company We offer powerful, precise and user-friendly solutions for every market and for every step of the abrasives process, enabling our customers to cut, shape, and finish all materials in the most complex and challenging applications. By working closely with end-users and grinding expert partners, we design and provide customized solutions to secure the best option for performance, cost, and safety. With more than 130 years of experience and more than 10,000 passionate employees, we’re proud to serve our customers through our network of 60 facilities, in almost 30 countries across all continents.

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Meet your presenter Todd Nate leads the North American manufacturing sector for Nokia Enterprise. Responsible for the vision, strategy, and execution, Nate has 25 years of OT experience enabling industrials to step-change their operational productivity/efficiency, business model flexibility, and financial position using advanced technology. His experience translating complex business drivers into successful technology transformation gives him a unique insight into the trends and dependencies of successful digital transformations. Nate earned his Bachelor of Science in Business at Indiana University and his MBA from Ball State University.

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As part of the ISO certification process, West Ohio Tool demonstrated its ability to provide products and services that meet customer and regulatory requirements.  The company also documented it upholds the seven quality management principles at the heart of ISO certification.

“Most manufacturers today are ISO certified, and they expect that same certification of their suppliers,” said West Ohio Tool President Rea King. “We’ve always maintained the highest standards in both our manufacturing operations and the tools we produce, so the certification is testament to that and further builds the already strong confidence our customers have in us.”

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Meet your presenter Matt Karesh is a technical sales engineer at Velo3D. He started his career in backup power generation before moving to commercial aviation, where he worked on high-pressure turbine blade design. Karesh started working with additive manufacturing in 2017 and has experience with several disciplines, including laser powder bed fusion, electron beam melting, and binder jetting. He holds a mechanical engineering degree from the Georgia Institute of Technology.

About the companyFrom software and hardware to complete product support, Velo3D is an end-to-end manufacturing solution that gives designers and engineers freedom to create what was previously considered impossible. In our quest to unlock tomorrow’s innovations, we enable parts to be printed to exacting standards of consistency, quality, and repeatability.

Advanced end-to-end solutions allow engineers to create the impossible. We help the world’s most innovative minds overcome complex challenges, taking metal AM to new levels of performance and efficiency.