Vitality stays a major think about industrial manufacturing processes. Excessive ranges of power consumption make manufacturing costlier and exacerbate the local weather disaster. A brand new kind of robotic expertise that wants 90% much less electrical energy than typical techniques is at the moment being developed in Saarland. The expertise makes use of light-weight, form reminiscence supplies to assemble novel, non-pneumatic, industrial gripper techniques that operate with out the necessity for extra sensors. The analysis group led by Professors Stefan Seelecke and Paul Motzki from Saarland College will probably be showcasing the expertise at this yr’s Hannover Messe.
Robotic arms are in use in numerous trendy industrial manufacturing settings. They’re used for a complete vary of duties, akin to holding workpieces in place, inserting elements, assembling printed circuit boards, in addition to transferring, loading or unloading components. And when they’re in use, most of them eat power continuous. Taken collectively, these industrial robotic arms eat a number of gigawatts {of electrical} energy. Most of the gripper techniques work pneumatically with compressed air, which will be unpleasantly loud. They’re usually heavy, their transferring components put on out over time, and so they are inclined to execute a continuing, extremely repetitive movement sample. This present expertise units limits on the extent of miniaturization that may be achieved, and small-scale grippers techniques with small grip factors are significantly arduous to understand. Standard robotic arms are additionally arduous to reprogram rapidly, and it is usually unsafe for human employees to work together intently with them on manufacturing strains.
However a brand new kind of drive expertise might nicely make the commercial robots of the long run lighter, compacter, extra versatile and extra power environment friendly. The expertise is predicated on light-weight form reminiscence alloys (SMAs), which the group of engineers led by Professors Paul Motzki and Stefan Seelecke at Saarland College and the Saarbrücken Heart for Mechatronics and Automation Expertise (ZeMA) are utilizing to construct novel robotic grippers. ‘The work we’re doing will help deliver a couple of vital discount in power consumption, decreasing manufacturing prices in addition to serving to to guard the local weather,’ explains Paul Motzki, Professor of Good Materials Programs for Modern Manufacturing at Saarland College and Scientific Director/CEO at ZeMA gGmbH.
The analysis group will probably be at this yr’s Hannover Messe the place they are going to be showcasing quite a lot of prototypes, together with vacuum gripper and jaw gripper techniques that may safely maintain and manipulate workpieces with out requiring the continual provide of power. ‘We are able to management these gripper techniques in actual time and at any time when wanted; all we have to do is apply a brief pulse of electrical present,’ explains Prof. Motzki.
The Saarbrücken gripper system is absolutely electrical and consists of bundles of ultrafine wires created from nickel-titanium form reminiscence alloy. These bundles of ultrafine wires act not solely as highly effective muscle tissue, however as nerve fibres as nicely. The behaviour of those wire bundles is because of a particular property of nickel-titanium alloy, specifically that it will probably change between two totally different crystal lattice constructions. If an electrical present flows by means of a wire created from nickel-titanium, the fabric heats up, inflicting it to undertake a distinct crystal construction with the end result that the wire turns into shorter. When the present is switched off, the wire cools down and returns to its earlier crystal lattice construction and its unique size. The fabric seems to ‘bear in mind’ its unique form and to return to it after being deformed — therefore the title ‘form reminiscence’ alloy. The wires are subsequently capable of exert remarkably massive forces for his or her measurement and will be made to set off tiny, managed motions in no matter good expertise the engineers have hooked up to those minute synthetic muscle tissue.
Paul Motzki explains the muscle energy of those tiny wire bundles as follows: ‘Nickel-titanium SMA has the best power density of all recognized drive mechanisms, so through the use of this materials, we’re capable of exert a considerable tensile pressure in very small areas.’ A wire with a thickness of solely half a millimetre can exert a pull of some 100 newtons, which is roughly the pressure exerted by 10 kg. However the researchers use bundles of a lot thinner, ultrafine wires, as extra wires imply a larger floor space and subsequently sooner cooling charges. Which means the wire ‘muscle tissue’ can ship speedy, excessive frequency motions and a secure tensile pressure. The engineering group in Saarbrücken truly maintain a world report on this space: Utilizing a bundle of 20 ultrafine wires, every with a diameter of solely 0.025 mm, they’ll exert 5 newtons of pressure at a frequency of 200 hertz (i.e. 200 cycles per second). In some functions, the dimensions of the pressure delivered is most essential, in others it’s the frequency with which the pressure is utilized. Utilizing the information acquired from a number of years of analysis, Motzki’s group is ready to tailor the composition of the wire bundles by way of wire thickness and variety of wires per bundle to fulfill the necessities of particular functions.
Utilizing progressive management and design methods, the engineers are growing drives that use SMA wires to create light-weight, manoeuvrable and cleanroom-compatible industrial robots. The expertise is below steady refinement in analysis and PhD tasks, which has enabled the Saarbrücken researchers to develop elastic gripper techniques with extremely versatile ‘fingers’ that may rapidly adapt to modifications within the form of a workpiece.
Standard grippers often depend on suggestions from sensors, however the expertise developed in Saarbrücken is self-sensing — the sensor properties are already constructed into the system. The system is managed by a semiconductor chip. ‘The form reminiscence wires successfully act as absolutely built-in sensors offering us with all the mandatory knowledge. An AI system exactly correlates {the electrical} resistance knowledge with a selected deformation of the wires. In consequence, the system at all times is aware of the precise place of every bundle of form reminiscence wires. The information-trained neural networks are capable of calculate positional info effectively and precisely even within the face of disruptive influences,’ explains Paul Motzki. The engineers can subsequently program the system to carry out extremely exact actions. By specifying {the electrical} resistance values, they’ll management the wires as wanted. ‘Not like the usual industrial robots in use right now, reprogramming is fast and straightforward with our system and may even be accomplished on the fly when mandatory. The gripper can adapt to the geometry of various workpieces whereas working,’ says Motzki.
The prototype jaw gripper developed for industrial functions strikes each rapidly and with pinpoint accuracy. The gripper holds the workpiece securely in a pincer-like grip so {that a} robotic arm dealing with system can then manoeuvre the workpiece to its desired vacation spot. The prototype being exhibited at this yr’s Hannover Messe can exert a pressure of 4 newtons, however the expertise is scalable by way of measurement, jaw stroke and pressure. The self-sensing properties of SMA wires allow the exact place and situation of the grippers to be monitored with none extra exterior sensors. And the grippers are capable of maintain the workpiece in place with out requiring power to be equipped. Relying on the gripping software, the Saarbrücken expertise can obtain power financial savings of over 90% relative to the traditional pneumatic grippers in use right now.
One other prototype being proven by the analysis group at Hannover Messe 2025 is a vacuum gripper that has versatile gripper fingers with vacuum suction cups situated on the fingertips. Right here, too, a brief electrical pulse is all that’s wanted to generate and later launch a load-bearing vacuum. The vacuum gripper mechanism is achieved by arranging bundles of ultrathin SMA wires right into a round muscle round a skinny metallic disc that may be made to flip up or down, like a frog clicker toy. Making use of {an electrical} pulse makes the wires within the ‘muscle’ contract and the disc flips its place, pulling on a rubber membrane that creates a vacuum if the gripper fingertips are involved with a floor. As soon as once more, no electrical energy is required with a view to maintain the workpiece in place, even when the gripper is holding a heavy object at an angle over an prolonged interval. ‘And the self-sensing performance signifies that our system has built-in situation monitoring, so the gripper is aware of if the vacuum created is sufficient to help the load’ says Motzki.
Background
The analysis group headed by Stefan Seelecke and Paul Motzki makes use of form reminiscence expertise for a variety of functions that embrace progressive cooling techniques, robotic grippers and progressive valves and pumps. The expertise continues to be developed by graduate college students and post-graduates conducting analysis as a part of their doctoral dissertation tasks. The group’s outcomes have been communicated extensively in scientific conferences in addition to in high-impact journals, with quite a few papers receiving worldwide recognition. The analysis work has additionally acquired help from quite a few sources, together with the multinational engineering and expertise firm Bosch and from the Saarland state authorities, which has supplied funding by means of the ERDF tasks ‘iProGro’ and ‘iSMAT’.
