Having been invented in 1983 and patented in 1986 by C. Hull the 3D printing technology (initially named “stereo lithography”) is a well-established production method in today’s industrial market. Forecasts predict an increase of 774% in the global turnover during the next 5 years – which makes 3D printing one of the most prospering markets in the near future. One of the various 3D printing methods is additive laser powder build-up welding. This technique is characterized by coating materials in powder form with the help of laser welding. The desired shape of the specific product is formed by following trajectories which are predefined prior to manufacturing. The energy of the laser melts the used metal powder forming a welding bead.
The final geometry is given its threedimensional contour by the overlapping of the welding beads based on the paths of the predefined trajectories. Optimization of the additive laser powder build-up welding focuses on economical processing with high quality and accuracy. Another focus lies on scalability: large scale on the one hand and implementing microstructures less than 100 µm on the other.1 The materials used for additive laser powder build-up welding are mainly:
Process of additive laser powder build-up welding
In the following, we will demonstrate the materialographic preparation process of a sample produced by additive manufacturing. In materialography, a sample taken from a work piece is called specimen.
A typical materialographic examination includes the following steps:
Examination by:
For this article a steel sample (X6Cr17, material number: 1.4016) manufactured by additive laser powder build-up welding was investigated. The first step was to obtain a smaller sample piece (=specimen) which is representative of the complete workpiece. This was achieved by using QATM’s precision cutter with a thin CBN (cubic boron nitride) blade (wheel thickness: 0.65 mm, wheel diameter: 153 mm).
The cutting was effected with a pulsed direct cut (0.2 mm forwards and 0.2 mm backwards) with a feed speed of 1 mm/s and a rotational speed of 4500 rpm. After cutting, the specimen was mounted in a hot mounting material (Epo black) with an hot mounting press to obtain a specimen which is easier to handle. Mounting was carried out at a pressure of 200 bar for 6 minutes at 180°C, followed by a cooling cycle of 6 minutes. Another advantage is the high degree of parallelism of the mounted specimens of 51 µm ±1 µm (the tolerances are based on the caliper used for height measurements of the specimens). The mounted specimens were ground (individual force) and polished (individual force) afterwards with a semiautomated grinding and polishing machine.
The grinding process was divided into two steps. The first one was plane grinding using a silicon carbide (SiC) grinding paper with grit size P240 to remove all deformations caused by the cutting process. This was followed by grinding with a SiC paper with grit size P600 to smoothen the surface for subsequent polishing steps. First, the specimen was prepolished with the hard Galaxy BETA polishing cloth and 9 µm polycrystalline diamond suspension, followed by a medium-hard cloth made of silk and 3 µm poly diamond suspension. The last step, called final polishing, was done on a soft synthetic polishing cloth and Eposil M. The detailed preparation parameters are indicated in this table:
步骤 | Medium | 润滑剂/悬浮液 | 速度 (rpm) | 试样夹具旋转方向 | 单点力 (N ) | Time (min) |
Grinding | SiC, P240 | 水 | 150 | 顺时针 | 30 | 1:00 |
Grinding | SiC P600 | 水 | 150 | 顺时针 | 30 | 1:00 |
抛光 | BETA | 酒精, 金刚石 9 µm(poly) | 150 | 逆时针方向 | 35 | 4:30 |
抛光 | GAMMA | 酒精, 金刚石 3 µm(poly) | 150 | 逆时针方向 | 35 | 4:00 |
抛光 | OMEGA | 水, Eposil M | 100 | 顺时针 | 30 | 1:30 |
Based on this preparation sequence, a finely polished specimen surface was obtained. Figure 3 shows an image taken with an incident optical microscope (incident light) at a magnification of 100.
Image of the prepared specimen surface. Due to the polished surface the light is reflected almost equally and the microstructure is not discernible.
As the light is reflected almost equally over the whole specimen surface, the microstructure remains invisible. Due to the nature of the human eye, a minimum difference in contrast of 10% is needed to make the contrast visible on any surface. This contrasting is achieved by etching. In our example, the etchant “V2A Beize” for pickling was used to contrast the surface by selective etching of the different phases of the investigated X6Cr17 steel. Etching was done for 45 s and the microstructure is very well discernible as can be seen in the picture.
Further examinations, like hardness testing, require a plane and smooth surface to provide reliable and meaningful results. The materialographic preparation process described above ensures that the specimen is ideally suited for hardness testing. QATM offers powerful instruments for micro-hardness testing and optical evaluation.
QATM offers a wide range of innovative and robust instruments for materialography, metallography and hardness testing. Our experts know the requirements of each branch of industry and and will be happy to assist in finding the right solution for your application.