Founded in 1968 and headquartered in Istanbul, TOFAS (Türk Otomobil Fabrikası A.S.) manufactures cars, taxis, and vans in Turkey for international sale. Products are offered under several brands, including Fiat (which jointly owns the company), Peugeot, Citroen, and Opel. The TOFAS-built Fiat Linea is Turkey's best-selling passenger car, while its Fiat Doblò (also produced as the Opel Combo) claims first place in the light commercial vehicle category.
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Nikon cross scanners installed on Hexagon CMMs
Since 2013, cross scanners from Nikon Metrology have been installed on two Hexagon DEA BRAVO horizontal arm CMMs equipped with a continuous wrist CW43 interface. Incorporating three lasers in a cross pattern, the XC65Dx-LS captures full 3D details of features and surfaces in a single scan. By digitizing complex features from three sides, the cross scanner acquires the complete 3D geometry of the features, driving the accurate extraction of positions and dimensions.
Smart laser intensity adaptation allows any surface, such as those with varying color or high reflectivity, to be scanned without the use of a matt spray or other user interaction. This is enabled by automatic, real-time adjustment of sensor settings between successive laser stripes and for each individual point along the laser stripe. The XC65Dx-LS installed at TOFAS has a longer stand-off distance and offers distinct advantages. By capturing geometry from up to 170 mm away, the scanner gains optimum access to body-in-white (BIW) structures and can scan over the clamps that hold components in position.
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The scanners can be used in combination with tactile probes for aligning a part or for a mixed measuring routine. DMIS-based CAMIO8 software from Nikon Metrology provides a rich programming environment, with intuitive software tools for both tactile and laser scanning applications. A wide variety of inspection tools are available, including full part-to-CAD comparison, intelligent feature extraction with geometric dimensioning and tolerancing, and profile analysis. CAMIO is optimized for processing large point clouds, making it perfectly suited to measuring sheet metal panels and assembled car bodies.
During vehicle development, the scanners are used instead of touch probes for inspecting both individual car panels as well as for complete diagnosing the BIW after the car’s sheet metal panels have been welded together but before the bonnet, doors, and boot lid have been added. In this way, the vehicle’s entire sheet metal structure is inspected to very close tolerances, showing the interaction between the panels and allowing parts issues to be separated from process issues. Also, completed vehicles are inspected, mainly for gap and flush spacing between different car panels.
Advantages of the laser-scanning-based inspection process
“The savings are significant when using scanners instead of tactile probes for feature and surface inspection of BIW on our CMM,” says Özgür Ogur, leader of the Diagnostics Measurement Lab at TOFAS in Bursa.
“Laser scanning fulfills our accuracy requirements, and there are no significant differences in accuracy between tactile and scanning,” Ogur continues. “We require 0.2-mm uncertainty on a 5.5-meter diagonal, and as the inspection device has to resolve to one-tenth of the tolerance band, the scanners need to measure down to 20 microns. Measurements have proven that the scanners achieve this requirement in line with their listed specifications.”
TOFAS is also pleased with the scanners’ time-saving capability. “Their repeatability of down to 1 micron is really excellent and beyond our expectations,” says Ogur. “Inspection is now twice as fast as when we used touch probes, reducing lead time between design iterations and raising efficiency.”
Diagnostic measurement of anything from individual components to finished vehicles is carried out on the Hexagon horizontal arm CMM using the Nikon Metrology laser scanning heads, which check for gap and flush as well as inspecting features and surfaces. The equipment is used continuously over two shifts every day, and it is rare to find touch probes on the end of the two arms. The data generated by the scanners give full geometrical detail by fully digitalizing the parts. The large amount of part-to-CAD comparison information provides greater insight when analyzing the inspection results, ultimately leading to faster decision making.
Scanning on the CMM has eliminated the need for dedicated, stand-alone measurement systems and supersedes the use of laser scanners on portable measuring arms. Compared with dual horizontal arms scanning, which would require two operators to measure both sides of a car, the CMM measures automatically and is inherently more accurate and repeatable. With portable scanning, an operator needs to be told which features to inspect, whereas on a CMM it is a simple matter of calling up a program from a library and starting the cycle.
Further advantages of scanning are that it greatly broadens the application scope of horizontal arm CMMs, allowing better use to be made of the capital investment. Moreover, the controlled, process-oriented measurements are ideal for statistical process control. The technology leads to faster detection of problems and more prompt corrective actions, as well as greater flexibility and economy in the quality control laboratory due to the ability to run inspection cycles unattended for long periods.
Virtual assembly to reduce the prototype phase
In such a dynamic production facility, the company needs a modern quality control function to support the development phase of new vehicle models. All body parts constantly undergo comprehensive checks, but the individual pieces of data collected do not show how well adjacent parts fit together. It is therefore necessary to assemble mating panels on high-precision fixtures, called meisterbocks, which replicate the body shop’s assembly tooling and process. In this way, design, fit, function, gaps, and flushness of sheet metal elements can be visually assessed, and measured dimensions can be compared with the CAD model of the car.
The ultimate goal of TOFAS is to be able to scan completely all prototype sheet metal panels and parts, and create a virtual assembly using the 3D digital copies for geometric evaluation in software. This verification approach is already revealing potential part-fitting issues and aims to reduce the duration of individual prototype cycles as well as the number of prototype iterations needed to produce different car panels. The 3D measurement data of initial prototype parts will also serve as a reference to analyze dimensional changes during serial production.
Fiat is leading the study project, and deployment is expected in one to two years.
Comparative ISO 10360 accuracy tests
None of the above would be possible if the laser scanners were not able to capture the BIW data accurately and repeatably. Because the scanners were able to capture the data in this way, Ogur and his colleague, aesthetics diagnosis expert Rahim Koşar, were able to go to considerable lengths to test the performance of the XC65Dx-LS against the traditional touch probe.
Comparative benchmarks were performed in accordance with ISO 10360 acceptance and reverification tests for CMMs, and three criteria were investigated: probing error (MPEP), length measurement error (MPEE), and tactile scanning error (MPETHP).
In the worst case, MPEP was 7 microns after five scans on a ceramic sphere, and in one of the zones, a 1-micron error was recorded. The catalogue value was given as 15 microns, so all results were acceptable. Five MPEE measurements of a ball bar in seven diagonal positions yielded sigma values of less than 7 microns. As scanning is done from different angles, the 25-mm sphere needs to be measured at five angular positions. Deviation was found to be 11 microns, within the 12 microns stated in the catalogue. All three error values were at least equivalent to those achieved with tactile probing.
Successful benchmarks on real parts
The TOFAS team took the trials a step closer to reality by laser scanning actual car parts. A Doblò side panel was selected, and its contours and geometrical features were inspected first by touch probing and then by laser scanning. The former measurements were taken as the nominal, and the latter values used to calculate the difference.
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Again, this showed that laser scanning is an acceptable procedure for quality control of BIW vehicles where, as an example, a tolerance band of < ±0.2 mm is required for surface measurement.
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Spheres were then attached to an assembled Doblò car to review diagonal length scanning accuracy. An uncertainty of 0.2 mm was observed over a length of 5.5 m, so scanning is considered acceptable for diagnostic measurements on a CMM with 45µm + 25L/1000 uncertainty.
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