Inspection of Laser Powder Deposited Layers

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11th European Conference on Non-Destructive Testing (ECNDT 2014), October 6-10, 2014, Prague, Czech Republic More Info at Open Access Database www.ndt.net/?id=16346 Inspection of Laser Powder Deposited Layers John RUDLIN 1, Donatella CERNIGLIA 2, Michele SCAFIDI 2, Charles SCHNEIDER 1 1 TWI, Granta Park Abington Cambridge CB21 6AL, UK +44 1223 899000 john.rudlin@twi.co.uk 2 University of Palermo, 90128 Palermo, Sicily. donatella.cerniglia@unipa.it Abstract Laser powder deposition is a process where a powder is sprayed on to a substrate at the same time as a laser is used to melt it. In this way layers of the powder material are built up into structures that can be very fine and complex. For critical requirements it is useful to inspect the structure as the layers are deposited as the final component may have considerable added value. The main challenge for the NDT methods are the small sizes involved, which in turn lead to detection of small flaws being required. Laser ultrasonics, laser thermography and eddy currents were identified as methods that might be deployed for the inspection. This paper describes the results obtained from these methods on a specially developed set of reference samples and on specific deposition samples with induced flaws. Keywords: Additive Manufacture, Laser deposition, eddy currents, laser ultrasonics, laser thermography 1 Introduction Laser powder deposition is an example of manufacturing technique known as additive manufacturing, which is becoming increasingly common, especially with a technique called 3D printing, in which structures are made in a plastic material by a nozzle depositing it on a surface. For metals this is less straightforward because of the high temperatures needed to melt the metal. One method of carrying out this heating is with a laser. A metal powder is sprayed on to a substrate at the same time as a laser is used to melt it. In this way layers of the powder material are built up into structures that can be very fine and complex. The layer size is typically 0.5mm-2mm wide and 0.3-0.5mm deep. For critical requirements it is useful to inspect the structure as the layers are deposited as the final component may have considerable added value. Typically the mainstream NDT methods are used to inspect large structures whose failure could possibly cause severe consequences, such as loss of life or environmental or economic damage. With the additive manufacturing process, NDT methods are required to inspect much smaller sizes, which in turn lead to detection of small flaws being required. Laser ultrasonics, laser thermography and eddy currents were identified as methods that might be deployed for the inspection. This work was carried out for INTRAPID project, with the following partners: Bytest (Italy, LPW (UK), Polkom (Poland), Tecnitest (Spain), Toyota (Belgium), University of Palermo (Italy) KCC (UK) and TWI (Abington and Sheffield) (UK). 2 Concept The concept of the project was that the NDT methods would be deployed on a robotically operated laser deposition system at TWI Yorkshire. The systems were arranged so that they

could be fitted on to the robot end effector in turn using simple mechanical attachments. In turn the system should be automated as far as possible to represent a manufacturing process. 3 Samples The test samples were divided into reference samples, in which machined flaws were produced in standard geometries by a wide range of techniques, and test samples which were made using deposition, with flaws induced or produced by a range of techniques. 3.1 Reference Samples The test samples included were (1) sheets with drilled holes 0.1mm dia to 0.7mm dia at different distances from one edge (inspection carried out from that edge (Figure 1) (2) samples with a raised portion with drilled holes in the raised portion (Figure 2), with holes generally 0.2mm diameter or less, samples with embedded holes and thickness variations (Figure 3). Inspection surface Depth Through hole 0.5mm Figure 1 Type 1 Reference Samples made by laser drilling Figure 2 Type 2 Samples made by EDM Microdrilling

D T1 T2 T3 T4 2T 15 50 T1 T2 D1 D2 D3 T3 3.2 Test Samples Figure 3 Type 3 and Type 4 Reference Samples made by diffusion bonding Test samples were made with an Inconel substrate and single layer deposit (Figure 4), with a flaw induced in each sample by special techniques. Figure 5 shows a typical flaw in this process. In some samples the surface produced by the deposited layer was removed to determine the effect of the surface on the NDT techniques (Figure 6). Figure 4 Deliberate Flaw induced in Inconel deposit (flaws are approximately 0.4mm long (into the paper)

Figure 5 Test Samples in Inconel (from left) deposited layer, surface skimmed, profile and some substrate removed 4 Inspection Methods 4.1 Eddy Currents The eddy current system uses an automated version of the Veritor instrument, and special probes for different tasks. Some features of the probe and the flaws were modelled to try and understand the optimum methods (1). Figure 6 shows this mounted on the robot arm with the deposition system to the right. The eddy current system produces a typical impedance plane display together with a file of an inspection. The eddy current system inspects initially for material and probe position and then for a scanned inspection. The data was collected by software developed in the project and criteria developed to report anomalies. Figure 6 Eddy Current System attached to Robot Arm. The deposition system can be seen on the right 4.2 Laser Ultrasonics The laser ultrasonic method was modelled prior to construction (2). It consisted of a pulsed laser to produce the ultrasonic signal and a laser interferometer to detect the vibrations produced (Figure 7). The latter was connected to an A to D converter, which was serviced by software developed in the project.

Transmitting Laser Interferometer 4.3 Laser Thermography Figure 7 Laser Ultrasonic System This equipment consisted of a laser and thermal camera as shown in Figure 8. The laser is basically continuous, but can be pulsed using suitable switching arrangements. The camera has additional lenses to reduce the field of view. In initial experiments a video recording of the laser heating was used, a system which enabled synchronisation of the laser pulse with the frame output of the camera was developed. The laser intensity and pulse length were varied to optimise the heating effect. Laser (head) Thermal Camera Figure 8 Laser Thermography system 5 Automation of Systems It was required that the inspection be carried out immediately after the deposition process. Therefore each system was mounted on plates that could be bolted in-turn to the end plate of the deposition robot. In this was the inspection device simply requires a translation calculation from the robot deposition path to follow the same path for the inspection. The software for each inspection system was integrated on to one computer together with an interface program to the robot and data analysis modules which could sentence a layer on the basis of pre-set acceptance criteria.

6 Results and Discussion There are two initial factors in the flaw detection capabilities of the techniques, the flaw size and the flaw depth below the surface. Surface condition was not an issue in the results from the reference samples but was in the case of the test samples this makes an impact. 6.1 Eddy Current The eddy current results have been recorded as the impedance plane screen (for test purposes) Figure 9 gives some examples of typical signals. The signal strength varies considerably, and semimechanical scans (ie the probe and sample were fixed and the latter was moved using a manual micrometer table).were needed. A range of frequencies and probes were used to try and establish the sensitivity. This shows that flaws of 0.4mm dia can be detected up to depths of 0.5mm at this frequency and in the geometry and materials of these reference samples. Indications were also obtained from some of the reference samples Type 3 and 4. 0.1mm diameter 0.2mm deep 0.35mm diameter,0.4mm deep Gain is 10dB less than above Figure 9 Detection of 0.1mm diameter hole, 0.2mm deep, and 0.35mm diameter 0.4mm deep in Reference sample Type 1. The wire in the flaw picture was 100μm diameter and was used for calibration of the flaw size. 6.2 Laser Ultrasonics Some examples of the laser UT results on examples of the reference samples are given in Figures 10-11. It can be seen that the disruption of the surface wave is the main mechanism by which flaws are detected in Figure 10. Therefore the sensitivity decreases significantly for flaws below 300μm deep, whatever the size. There are additional indications from diffracted or reflected waves that can be seen above (i.e. later than) the surface wave where this is not interrupted in Figures 11 but these are quite weak for reliable detection. No indications could be obtained on reference samples Type 3 and 4. The indications on the deposited samples

show that near-surface flaws in an Inconel deposit can be detected in the same way as the reference samples (Figure 12). Surface Wave 0.6mm diameter/0.2mm deep Figure 10. Example of indications from Laser UT from Type 1 Reference sample with flaw close to surface: Map of displacement as a function of time of flight and distance along the surface 0.35mm dia/0.4mm deep Figure 11. Example of indications from Laser UT from Type 1 Reference sample with flaw away from surface: Map of displacement as a function of time of flight and distance along the surface. Figure 12 Indication from Inconel deposited sample with induced flaw

6.3 Laser Thermography The detection of a flaw by laser thermography is by means of asymmetry in the heating effect of the laser on the surface. Examples can be seen in Figures 13. Detection of sub-surface flaws was quite difficult and inconsistent and no indications were found for reference samples 3 and 4. Luminance 65,750 65,466 65,450 65,400 65,350 65,300 65,250 Flaw 0.6mm dia 0.2mm deep Flaw 0.14mm dia 0.1mm deep 64,950 65,224 Luminance 66,100 65,535 65,500 65,400 65,300 65,200 65,100 64,500 65,023 o nket ix rmeh o nket ix rmeh Video 15:14:16 13/06/2013 Video 11:31:53 13/06/2013 6.4 Summary Figure 13 Examples of outputs from laser thermography system Detailed results from the systems were analysed using the maximum likelihood method to obtain a graph showing how the depth and size of a flaw can be detected by each method. Examples of these, for one frequency of the eddy current tests and the laser UT tests are shown in Figures 14 and 15. It should be noted that these results are only for the equipment procedure materials and flaw types investigated. Also they do not extend beyond the range of the data. It can be seen that the eddy current detection at 90% POD is around 0.2mm diameter of the flaw at the surface, and around 0.6mm at 1mm depth. The Laser UT gives 90% POD at 0.1mm at the surface and more than 0.9mm at 1mm depth. This range of data needs to be extended for a wider range of flaws and procedures to enable optimum choices to be made.

Figure 14 Results and Analysis of Eddy Current tests at 2MHz Figure 15 Detection data and analysis from Laser UT

7 Conclusions Equipment was developed and demonstrated for the inspection of laser powder deposited layers. The capabilities of the inspection techniques used were obtained. 8 References 1 S. Majidnia and J. Rudlin Depth of Penetration Effects in Eddy Current Testing, BINDT Conference Daventry UK, September 2012. 2 D Cerniglia, M Scafidi, A Pantano S-P Santospirito Laser Ultrasonic Technique for Laser Powder Deposition Inspection 13th Int. Symposium on Non-destructive Characterization of Materials, Le Mans), May 2013. 9 Acknowledgements This work was carried out for INTRAPID project, with the following partners: Bytest (Italy, LPW (UK), Polkom (Poland), Tecnitest (Spain), Toyota (Belgium), University of Palermo (Italy) KCC (UK) and TWI (Abington and Sheffield) (UK). This work was funded by REA under contract FP7-SME-2011-283833. Thanks are due to the SMEs in the project for permission to publish. Thanks are also due to Roger Fairclough and Phil McNutt of TWI Sheffield, and Matt Robson of TWI Cambridge for preparation of samples; Oliver Gilmour (TWI) and Phil McNutt for interfacing and controlling the robot; Bin Luo, Kamil Slyk and S-P Santospirito (KCC) for software development. More details can be found in http://www.intrapid.eu/

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