Zusammenfassung der Projektergebnisse

The project aims to significantly increase the deposition rate of laser metal deposition (LMD) of IN718 (from ~ 0.5kg/h in traditional LMD to above 5kg/h) to achieve rapid manufacture of large high-performance high-value metal structural parts. The room temperature and high temperature mechanical properties of HDR-LMD IN718 were improved through process optimization and microstructure control. The research results are as follows: (1) A HDR-LMD powder nozzle was developed and the powdery materials were characterized. Based on the modified coaxial nozzle, an additional HDR-LMD nozzle, which allows a powder mass flow of more than 6 kg/h has been developed. In comparison to the GA-powder, the particles of the PREP powder are nearly ideally spherical in shape. Little to no hollow particles or particles featuring satellites have been observed. (2) The influence of the process parameters on porosity, track geometry, track area, dilution zone, deposition rate as well as powder efficiency were studied and the proper process parameters for a deposition rate of 1.8kg/h were developed (laser power is 3kW; laser spot diameter 4mm; scanning speed 1500mm/min; powder mass flow 2.3kg/h). (3) The effects of powder characteristics on the microstructure and tensile properties were investigated. The deposition by HDR-LMD with GA powder and PREP powder was investigated and compared. Compared to PREP powder, the porosity is higher, grains are finer and the volume fraction of Laves phase is lower with the GA powder. Using the same heat treatment, all the average tensile values of the PREP samples are slightly lower compared to the ones of the GA samples: yield strength, 5.4%; tensile strength, 2.0%; elongation, 9.1%. (4) The effects of the gas environment on the microstructure were investigated. HDR-LMD Inconel 718 deposited in air and argon environment was compared. The results show that the use of a global protective environment (argon) had no significant benefit for the deposition of IN718 alloy. (5) The powder stream concentration and temperature evolution were characterized and the particle temperature in the laser beam was analyzed. By using the self-radiation effect from the powder stream heated by the laser irradiation, grey images of the high temperature powder stream were obtained by high-speed photography. The grey value was corrected considering the divergent characteristics of the powder stream to correspond to the temperature change. A novel experimental method for characterizing the temperature evolution of the powder stream under the laser irradiation was developed. Meanwhile, the mathematical analysis of the particle temperature evolution in the laser beam was conducted successfully. (5) The nonlinear temperature evolution behaviour of the powder particles in the laser beam was calculated considering different process conditions. (i) It shows that by decreasing the speed and size of powder particles or increasing the laser power, the incident particle temperature reaching the deposition surface can be sufficiently increased. (ii) With the decrease of the particle speed from 9.3 m s-1 to 3.9 m s-1, the particle temperature at theoretical deposition surface is increased by 144%. (iii) In particular, the increase of the powder incident angle can significantly increase the incident temperature of powder particle. The temperature of the 65° incident particle is increased by 54.4% relative to that of the 50° incident particle. (iv) Due to the effects of the laser energy distribution along the moving trajectories, the powder particles that cross the centre axis of the laser beam and fall near the edge of the laser spot on theoretical deposition surface have the highest incident temperature. (v) Single-pass deposition experiments show that the enhancing interaction effect between laser beam and powder stream can effectively improve deposition quality and save energy. 20% and 30% laser power were saved to obtain good deposition quality by increasing powder stream incident angle and decreasing the particle speed, respectively. (6) The influence of heat treatment on the microstructure was investigated. The two employed solution heat treatment regimes are 1100 ℃×0.5 h/WQ+720 ℃ ×8 h/FC to 620 ℃/8 h/AC (Type-S) and 1100 ℃×1h/WQ+720 ℃×8 h/FC to 620 ℃/8 h/AC (Type-L). The recrystallization degree of type-L sample is higher than that of type-S and twins only exist in the former one. In addition, niobium segregation and Laves phases. Moreover, the remained granular sub-micron particles in both sample types are preserved. The tensile tests result show that both types of samples have similar yield strength and tensile strength, whereas the elongation of type-L is superior to that of type-S. The higher elongation of type-L sample is due to the existence of twins and the relatively uniform grain in it. The fracture mechanism of both samples is micro-voids coalescence ductile rupture. The separation of the granular sub-micron particles and g matrix is the main nucleus of the micro-void. (7) The different heat treatment systems were designed to investigate the effect of the heat treatment on the mechanical properties of the block sample. The result showed that the tensile test results indicate that by heat treatment, tensile strength and 0.2% yield strength of IN718 formed by HDR-LMD were improved, while the ductility was reduced, but all of these indexes exceeded AMS properties of casting and wrought IN718. Combining strength and plasticity values, the S15 +DA is the most suitable heat treatment system for room temperature tensile properties of HDR-LMD IN718. The S30+DA has the best strength and plasticity and its tensile properties at 650℃ can be comparable to the AMS wrought standard. The stress rupture testing was performed on RC1230 durable performance test machine at 650 ℃ and 725 MPa. The plasticity has been improved for HDR-LMD IN718 and exceeded the wrought standard (15%) by the heat treatment. However, the stress rupture life is still lower than the wrought standard. The creep testing was performed at 595℃ and 825MPa and found that the S30 +DA sample has better high temperature creep properties.

Projektbezogene Publikationen (Auswahl)

• A comparative study of Inconel 718 formed by high deposition rate laser metal deposition with GA powder and PREP powder, Materials and Design. 107 (2016) 386-392
  Chongliang Zhong, Jing Chen, Stefanie Linnenbrink, Andres Gasser, Shang Sui, Reinhart Poprawe
  (Siehe online unter https://doi.org/10.1016/j.matdes.2016.06.037)
• The failure mechanism of 50% laser additive manufactured Inconel 718 and the deformation behavior of Laves phases during a tensile process, International Journal of Advanced Manufacturing Technology. 91 (2017): 2733-2740
  Shang Sui, Jing Chen, Xianliang Ming, Shaoping Zhang, Xin Lin, Weidong Huang
  (Siehe online unter https://doi.org/10.1007/s00170-016-9901-9)
• The influence of Laves phases on the high-cycle fatigue behavior of laser additive manufactured Inconel 718, Materials Science & Engineering A. 695 (2017) 6-13
  Shang Sui, Jing Chen, Enxiang Fan, Haiou Yang, Xin Lin, Weidong Huang
  (Siehe online unter https://doi.org/10.1016/j.msea.2017.03.098)
• The tensile deformation behavior of laser repaired Inconel 718 with a non-uniform microstructure, Materials Science & Engineering A. 688 (2017) 480-487
  Shang Sui, Jing Chen, Rui Zhang, Xianliang Ming, Fencheng Liu, Xin Lin
  (Siehe online unter https://doi.org/10.1016/j.msea.2017.01.110)
• Influence of solution heat treatment on microstructure and tensile properties of Inconel 718 formed by high-depositionrate laser metal deposition, Journal of Alloys and Compounds. 740 (2018) 389- 399
  Shang Sui, Chongliang Zhong, Jing Chen, Andres Gasser, Weidong Huang, Johannes Henrich Schleifenbaum
  (Siehe online unter https://doi.org/10.1016/j.jallcom.2017.11.004)
• Microstructures, tensile properties, and fracture mechanisms of Inconel 718 formed by HDR-LMD with PREP and GA powders, International Journal of Advanced Manufacturing Technology. 96 (2018): 2031-2041
  Chongliang zhong, Jing Chen, Andres Gasser, Shang Sui, Johannes Henrich Schleifenbaum
  (Siehe online unter https://doi.org/10.1007/s00170-018-1662-1)
• Microstructures and stress rupture properties of pulse laser repaired Inconel 718 superalloy after different heat treatments, Journal of Alloys and Compounds. 770 (2019): 125-135.
  Shang Sui, Jing Chen, Liang Ma, Wei Fan, Hua Tan, Fencheng Liu, Xin Lin
  (Siehe online unter https://doi.org/10.1016/j.jallcom.2018.08.063)
• Study of nickel-based super-alloys Inconel 718 and Inconel 625 in high-deposition-rate laser metal deposition, Optics and Laser Technology. 109 (2019): 352-360
  Chongliang Zhong, Jochen Kittel, Andres Gasser, Johannes Henrich Schleifenbaum
  (Siehe online unter https://doi.org/10.1016/j.optlastec.2018.08.003)
• The influence of Laves phases on the room temperature tensile properties of Inconel 718 fabricated by powder feeding laser additive manufacturing, Acta Materialia. 164 (2019) 413-427
  Shang Sui, Hua Tan, Jing Chen, Chongliang Zhong, Zuo Li, Wei Fan, Andres Gasser, Weidong Huang
  (Siehe online unter https://doi.org/10.1016/j.actamat.2018.10.032)
• Investigation of dissolution behavior of laves phase in inconel 718 fabricated by laser directed energy deposition, Additive Manufacturing.32 (2020) 101055
  Shang Sui, Jing Chen, Zuo Li, Haosheng Li, Xuan Zhao, Hua Tan
  (Siehe online unter https://doi.org/10.1016/j.addma.2020.101055)
• The microstructure evolution and tensile properties of Inconel 718 fabricated by highdeposition-rate laser directed energy deposition, Additive Manufacturing. 31 (2020) 100941
  Zuo Li, Jing Chen, Shang Sui, Chongliang Zhong, Xufei Lu, Xin Lin
  (Siehe online unter https://doi.org/10.1016/j.addma.2019.100941)