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From prototype to final product - ready-to-install ball bearings from the 3D printer

  • What was needed: plain bearings for the steering system in the 3D-printed vehicle
  • Manufacturing method: filament extrusion (FDM)
  • Requirements: little play, high strength, high abrasion resistance
  • Material: iglidur I150
  • Industry: automotive sector
  • Success from the collaboration: good surface quality, faster production thanks to tool-free 3D printing, more time for development, little to no bearing clearance
 
The application at a glance:
The company Scaled 3D from Great Britain has developed a four-wheeled vehicle in its “Chameleon” project that consists exclusively of 3D-printed components. During vehicle tests, the steering system design attracted negative attention. The steering bearings had too much clearance and lots of wear. In order for the application to remain fully 3D printed, the company began looking for a tough, wear-resistant material that would be more suitable for the bearing points. After various tests in large and small and formats with the iglidur I150 tribofilament, the development team finally designed a five-part plain bearing that had very little clearance and was significantly more abrasion-resistant than bearings made of conventional plastic. This ensured that the bearing could continue to come entirely from a 3D printer.
 
Three steps to an abrasion-resistant 3D-printed component
The "Chameleon" project by Scaled 3D, a UK-based company, aimed to develop a vehicle completely from the 3D printer. The "Chameleon" project by Scaled 3D, a UK-based company, aimed to develop a vehicle completely from the 3D printer.

Problem

The vehicle's steering system had too much clearance and quickly became imprecise. It also ran the risk of wearing out quickly. So steering bearings with much less clearance that would fit into the existing shape of the rest of the vehicle had to be made. Plain bearing depth was not to exceed 20mm. The lower of the two bearings also had to have a split inner ring to allow mounting with the steering column, which has two sets of radial bolts at each end. The components also had to have significantly greater strength than the previously installed bearings made of standard PLA.
 

Solution

Scaled 3D found the perfect material for its "Chameleon" project in the tribologically optimised iglidur I150-PF tribofilament. The filament is very easy to process in a large-volume printer and offers good mechanical properties in terms of strength, toughness, and layer adhesion in sliding applications. The bearing was converted into a five-piece ball bearing that was initially tested as a prototype. During the tests, the clearance in the bearing was very low under eccentric loads during rotation. The tests in the development phase were already very meaningful, as the final components would be manufactured with the same process.
 

The "Chameleon" project - individual, sustainable application

The main goal of the "Chameleon" project from the UK was to develop a vehicle that comes entirely from the 3D printer. The idea behind the project was the change from mass production to fast, customer-specific production. At the same time, no-tool additive manufacturing was to allow recycled material to be used. According to Scaled 3D, it will be possible to use 100% recycled material in 3D printed vehicles and structures in the future. So far, the Chameleon team has managed to work with 30% recycled material in the first prototype of 2020. The speed with which parts can be 3D-printed is of special benefit to this project: a maximum of 83 minutes printing time for a large part (1.375 kg) meant that these parts could be drawn, printed and tested on the same day. The great speed advantage over such processes as milling and injection moulding had a very positive influence on the freedom of vehicle development, which was supported by the design freedom in the geometry of the parts.
 
The bearings for the steering system also come from the large-scale printer The bearings for the steering system also come from the large-scale printer

The path to the right bearings

In order to get an overview of the iglidur I150 tribofilament's tribological properties, the company first tested the components in a small format. First, nested cylinders were printed, their untreated surfaces already of very good quality compared to other materials. Parts were then printed in a large format, and their good surface quality was among their impressive features. The ball bearing to be replaced was then reprinted from iglidur I150. The I150 races and the ball bearing cage proved to be good slide partners for low-friction operation. In the end, a five-piece ball bearing was created.
 
The ball bearing prototype: conventional plastic on the left, iglidur I150 on the right The ball bearing prototype: conventional plastic on the left, iglidur I150 on the right

The all-rounder among the igus tribofilaments - iglidur I150

During the tests on the iglidur I150 ball bearing, the clearance was very low under eccentric loads during rotation. A double bearing system was then developed to fit into the Chameleon steering system. According to Scaled 3D, the print quality of iglidur I150 bearings is comparable to that of ASA and much better than conventional PLA. Despite a layer height of 1mm, the surface finish was very good. In addition to the good component quality, the company is also pleased with the easy assembly of the parts. The tribofilament is suitable for both small applications and projects with the large-scale printer. It has good mechanical properties and is therefore suitable for most applications and 3D printers. iglidur I150 is also food-compliant according to EU Regulation 10/2011 and is suitable for applications in the food and packaging industries.
 
Further information about iglidur I150
The iglidur I150 tribofilament can be used with all 3D printers. The iglidur I150 tribofilament can be used with all 3D printers.

Other application examples for 3D printed components can be found here:

All customer applications at a glance


The terms "Apiro", "AutoChain", "CFRIP", "chainflex", "chainge", "chains for cranes", "ConProtect", "cradle-chain", "CTD", "drygear", "drylin", "dryspin", "dry-tech", "dryway", "easy chain", "e-chain", "e-chain systems", "e-ketten", "e-kettensysteme", "e-loop", "energy chain", "energy chain systems", "enjoyneering", "e-skin", "e-spool", "fixflex", "flizz", "i.Cee", "ibow", "igear", "iglidur", "igubal", "igumid", "igus", "igus improves what moves", "igus:bike", "igusGO", "igutex", "iguverse", "iguversum", "kineKIT", "kopla", "manus", "motion plastics", "motion polymers", "motionary", "plastics for longer life", "print2mold", "Rawbot", "RBTX", "RCYL", "readycable", "readychain", "ReBeL", "ReCyycle", "reguse", "robolink", "Rohbot", "savfe", "speedigus", "superwise", "take the dryway", "tribofilament", "tribotape", "triflex", "twisterchain", "when it moves, igus improves", "xirodur", "xiros" and "yes" are legally protected trademarks of the igus® GmbH/ Cologne in the Federal Republic of Germany and where applicable in some foreign countries. This is a non-exhaustive list of trademarks (e.g. pending trademark applications or registered trademarks) of igus GmbH or affiliated companies of igus in Germany, the European Union, the USA and/or other countries or jurisdictions.

igus® GmbH points out that it does not sell any products of the companies Allen Bradley, B&R, Baumüller, Beckhoff, Lahr, Control Techniques, Danaher Motion, ELAU, FAGOR, FANUC, Festo, Heidenhain, Jetter, Lenze, LinMot, LTi DRiVES, Mitsubishi, NUM,Parker, Bosch Rexroth, SEW, Siemens, Stöber and all other drive manufacturers mention on this website. The products offered by igus® are those of igus® GmbH