Water-atomized Powder Research Articles

Effects of particle characteristics on the microstructure and mechanical properties of 17-4 PH stainless steel fabricated by laser-powder bed fusion

The effects of powder characteristics (powder shape, size and type) and processing conditions (laser power and scanning speed) on the mechanical properties and microstructures of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoretical density, ultimate tensile strength, hardness of L-PBF parts are sensitive to energy density and starting powder shape, size and type. The density and mechanical properties of both water and gas-atomized powders increased with increased energy density. The gas-atomized (D50 = 13 μm) powders which are spherical in shape and water-atomized (D50 = 17 μm) powders of high tap density produced low-porosity and high-density (~97% density) L-PBF parts at low energy densities of 64 and 80 J/mm3. The increase in energy density to 104 J/mm3 resulted in high dense (97 ± 0.5%) water- and gas-atomized powders L-PBF parts. However, even at a high % theoretical density (97 ± 1%), the properties of L-PBF parts varied over a relatively large range (UTS: 500–1100 MPa; hardness: 25–39 HRC; elongation: 10–25%). This large variation in mechanical properties could be attributed the martensite and austenite phase as well as grain size in the L-PBF parts. Furthermore, the martensite and austenite phase content and of the L-PBF parts were also sensitive to the energy density and starting powder type.

Thermoplastic deformation of ferromagnetic CoFe-based bulk metallic glasses

The superplastic deformation behavior of the ferromagnetic Co31Fe31Nb8B30 bulk metallic glass (BMG) in the supercooled liquid region was investigated. At a given temperature, the BMG exhibits a Newtonian behavior at low strain rates but a non-Newtonian behavior at high strain rates. The high thermal stability of this glassy alloy system offers an enough processing window to thermoplastic forming (TPF), and the strong processing ability was examined by simple micro-replication experiments. It is demonstrated that the TPF formability on length scales ranging down to nanometers can be achieved in the selected experimental condition. Based on the analysis of deformation behavior, the nearly full density sample (i.e. nearly 100%), was produced from water-atomized glassy powders and consolidated by the hot-pressing technique. The sample exhibits good soft-magnetic and mechanical properties, i.e., low coercive force of 0.43 Oe, high initial permeability of 4100 and high Vickers hardness 1398. These results suggest that the hot-pressing process opens up possibilities for the commercial exploitation of BMGs in engineering applications.

Additive manufacturing using water atomized steel powders

As additive manufacturing becomes a highly utilized system for research based projects and industrial applications, developments will be made to optimize machine capability and productivity. One of the main topics of development focuses on the quality and characteristics of the powder material used in the system.

Rheological properties of gas and water atomized 17-4PH stainless steel MIM feedstocks: Effect of powder shape and size

Influence of powder shape resulting from the fabrication route (gas or water atomization) together with the effect of mean particle size and solid loading on rheological properties of highly filled metal powder feedstocks was investigated as a key to processing of Metal Injection Molding (MIM) parts without voids and cracks. Eight 17-4PH gas or water atomized powders varying in the mean particle diameters from 3 to 20μm were admixed into paraffin wax/high density polyethylene (50/50) binder at powder loadings up to 70vol.%. The relative viscosity data obtained from capillary rheometer was fitted with rheological models to evaluate maximum loading along with the determination of the same parameter using time dependent torque measurement. It was found out that for coarse particles the processability in terms of rheological behavior is better in case of gas atomized powders in accordance with previous findings, but in case of fine powders, water atomized powders showed higher performance.

Treatment of ferrous melts for the improvement of the sphericity of water atomized powders

This study investigated the effect of a magnesium treatment of ferrous melts before water atomization on powder properties such as their shapes, flows, and apparent and tap densities. Three different ferrous alloys were studied, a high carbon steel alloyed with silicon, a hypereutectic cast iron, and a 304 stainless steel. All the powders that were treated with Mg were more spherical and contained fewer and smaller internal pores. All the Mg-treated powders had better flow and larger apparent and tap densities. The improved sphericity of the Mg-treated particles is caused by a larger solidification time and a smaller spheroidization time of the droplets. The larger solidification time is the result of the creation of a continuously renewed insulating Mg gas layer during solidification of the droplets. The smaller spheroidization time is a result of a larger surface tension of the melt from the reaction of Mg with dissolved sulfur. The decreased amount and size of internal porosities is also caused by the larger surface tension of the melt. This new technology is highly cost-effective and can benefit to the development of the additive manufacturing market.

Two-Phase Master Sintering Curve for 17-4 PH Stainless Steel

The sintering behavior of 17-4 PH stainless steel has been efficiently characterized by a two-phase master sintering curve model (MSC). The activation energy for the sintering of gas-atomized and water-atomized 17-4 PH powders is derived using the mean residual method, and the relative density of both powders is well predicted by the two-phase MSC model. The average error between dilatometry data and MSC model has been reduced by 68 pct for gas-atomized powder and by 45 pct for water-atomized powder through the consideration of phase transformation of 17-4 PH in MSC model. The effect of δ-ferrite is considered in the two-phase MSC model, leading to excellent explanation of the sintering behavior for 17-4 PH stainless steel. The suggested model is useful in predicting the densification and phase change phenomenon during sintering of 17-4 PH stainless steel.

Study of the uniaxial cold compaction of AISI 316L stainless steel powders through single action tests

The behavior during uniaxial cold compaction of a commercial mix of a water atomized austenitic stainless steel powder and a lubricant was investigated by carrying out single action tests and recording the force applied by the upper punch to the powder column, the force applied to the die, and the displacements of the crosshead and of the die. Data collected during the experiments were elaborated using different correlations between the axial stress and the radial stress in the powder column: the Poisson correlation for the elastic deformation of the powder column, and the Von Mises criterion for plastic deformation.Friction coefficient decreases on increasing relative density up to ρr=0.7, then it stabilizes on 0.15. The flow stress of the powder mix increases with the relative density by a power law. The radial stress transmission coefficient increases with relative density, with two distinct trends in the ranges where either elastic or plastic deformation of the powder column predominate.

Effects of Powder Attributes and Laser Powder Bed Fusion (L-PBF) Process Conditions on the Densification and Mechanical Properties of 17-4 PH Stainless Steel

The effects of powders attributes (shape and size distribution) and critical processing conditions (energy density) on the densification and mechanical properties of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoretical density, ultimate tensile strength and hardness of both water- and gas-atomized powders increased with increased energy density. Gas-atomized powders showed superior densification and mechanical properties when processed at low energy densities. However, the % theoretical density and mechanical properties of water-atomized powders were comparable to gas-atomized powders when sintered at a high energy density of 104 J/mm3. An important result of this study was that, even at high % theoretical density (97% ± 1%), the properties of as-printed parts could vary over a relatively large range (UTS: 500–1100 MPa; hardness: 25–39 HRC; elongation: 10–25%) depending on powder characteristics and process conditions. The results also demonstrate the feasibility of using relatively inexpensive water-atomized powders as starting raw material instead of the typically used gas-atomized powders to fabricate parts using L-PBF techniques by sintering at high energy densities.

Effect of powder fabrication process on microstructure and mechanical properties of selective laser melted metals for biomedical applications

Event Abstract Back to Event Effect of powder fabrication process on microstructure and mechanical properties of selective laser melted metals for biomedical applications Naoyuki Nomura1, Su Yalatu2, Yusuke Tsutsumi2, Takao Hanawa2, Takayuki Nakamoto3, Takahiro Kimura3, Keiko Kikuchi1 and Akira Kawasaki1 1 Tohoku University, Department of Materials Processing, Japan 2 Tokyo Medical and Dental University, Institute of Biomaterials and Bioengineering, Japan 3 Technology of Research Institute of Osaka Prefecture, Machining & Molding Section, Japan Introduction: Selective laser melting (SLM) process has been received much attention because this process enables us to fabricate complicated shape without mold or conventional cutting tools. By utiliing this process, it is expected to achieve custom-made implants for patients. In addition, some metals fabricated through SLM process shows different microstructure and mechanical properties compared to as-cast or forged metals. We have been focusing on cobalt-chromium-molybdenum (Co-Cr-Mo) alloys which have been widely used in orthopedics and dentistry. Co-Cr-Mo alloys show excellent strength and wear resistance but limited ductility owing to the formation of martensite (hcp) and the precipitation of carbides or sigma phase. Our group has previousely reported that elongation and strength of high Cr and N Co-Cr-Mo alloy showed higher strength compared to the as-cast alloy [1]. This is mainly due to the suppression of martensite and sigma phase. Therefore, it can be concluded that the effects of high Cr and N with the combination of applying the SLM process works for enhancing the mechanical properties. In this study, we focused [on the processing of high Cr and N containing Co-Cr-Mo powder, because the SLM builds could be suffered from impurities from the powder. Threfore, the purpose of this study is to fabricate high Cr and N containing Co-Cr-Mo powder with different atomization process and investigate their microstructure and mechanical properties. Materials and Methods: Co-33Cr-5Mo-N alloy powders were prepared using gas atomization and water atomization processes. Ar gas was used in the gas atomization. Size distribution was evaluated by optical microscope. The surface of the powder was analysed by SEM-EDX. Chemical composition of these powders were determen by ICP-MS. The selective laser melting (SLM) process was carried out using the gas atomized and water atomized powders under the diameter of 45 microns. Tensile test specimens with the guage length of 18 mm were build to evaluate mechanical properties and microstructure. Results and Discussion: Fig. 1 shows SEM images of gas atomized and water atomized Co-33Cr-5Mo-N alloy powders. Spherical shape and smooth surface with dendritic morphology was observed in the gas atomized powders. On the other hand, relatively deformed sphere shape with gray contrast was observed in the water atomized powders. This deformation was caused by the higher impact enegy from water. SEM-EDX analyses revealed that Si and oxygen were enriched in the gray area. This suggests that the water atomized powder was oxidized during the process, although such area could not be seen at the gas atomized powder. Table 1 summarizes the mechanical properties of SLMed Co-Cr-Mo alloys using gas and water atomised powders. The SLMed high Cr and N Co-Cr-Mo alloys showed higher tensile propertites compared to the as-cast alloy. Comparing the builds using gas and water atomized powders, almost the same properties was achierved. However, when the energy density, which was determined by the SLMed parameter, was decreased, the strength and elongation of the SLM build using water atomized powder showed higher values compared to those using gas atomized powder. Since the porosities in the builds using gas atomized powder was higher than those using water atomized powder at the low energy density, this may cause the mechanical properties difference in the SLMed builds. Figure 1. SEM images of high–Cr and –N Co-Cr-Mo alloy powders fabricated by (a) gas atomization process and (b) water atomization process. Table 1. Mechanical properties of SLMed Co-Cr-Mo alloys using gas and water atomized powders. Conclusion: The powder fabrication process gave influences on the porosity of the SLMed builds, which leads to the mechanical properties difference at the same energy density for the SLM process. Oxygen content in the powder could be one of the important factor, and it needs further investigation.

Influence of binder system and temperature on rheological properties of water atomized 316L powder injection moulding feedstocks

Hatasiz toz enjeksiyon kaliplama (TEK) islemi icin besleme stoklarinin reolojik ozellikleri iyi bilinmelidir. Bu calismada 316L paslanmaz celik tozunun reolojik ozelliklerine baglayici sisteminin etkisini belirlemek amaciyla 2 farkli baglayici sistemi kullanilarak besleme stoklari hazirlanmistir. Deneysel calismalarda 20 mikron alti su atomize 316L paslanmaz celik tozu kullanilmistir. Heptan icerisinde cozunebilen parafin wax (PW) esasli ve su icerisinde cozunebilen polietilenglikol (PEG) esasli iki farkli baglayici sistemi hazirlanmistir. Her iki baglayici sistemi icerisinde iskelet baglayici olarak polipropilen (PP) ve yaglayici olarak stearik asit (SA) kullanilmistir. Baglayici sistemleri kuru olarak turbula marka 3 boyutlu karistiricida 30 dakika karistirilarak hazirlanmistir. Toz ve baglayici sistemleri kullanilarak hazirlanan besleme stoklarinin reolojik ozellikleri kilcal reometre kullanilarak karakterize edilmistir. Kilcal reometrenin sicakligi 150-200 °C araliginda basinc degerleri ise 0.165-2.069 MPa arasinda degistirilmistir. PEG esasli baglayici sistemi kullanilarak hazirlanan besleme stoklarinda toz tasima kapasitesi hacimce %55’e, PW esasli baglayici sistemi kullanilarak hazirlanan besleme stoklarinda ise %61’e cikartilmistir. PEG esasli besleme stoklarinda en dusuk viskozite degeri 304.707 Pa.s olarak, PW esasli besleme stoklarinda en dusuk viskozite degeri 48.857 Pa.s olarak elde edilmistir.

Influence of binder system and temperature on rheological properties of water atomized 316L powder injection moulding feedstocks

In order to obtain a proper powder injection molding the rheological behavior of feedstocks should be known. To determine the binder effect on the rheological behavior of 316L stainless steel powders feedstock two different feedstock were prepared. In the current experiments water atomized 316L stainless steel powders (-20 µm) were used. Two types of binders, one of which is mainly paraffin wax can be dissolved in heptane and the other Polietilenglikol (PEG) based and can be dissolved in water, were used. Polypropylene was used as binder and steric acid was used as lubricant for both binder systems as skeleton binder. Dry binder system were mixed for 30 min in a three dimensional Turbola. Capillary rheometer was used to characterize the rheological properties of feed stocks at 150-200 °C and a pressures of 0.165-2.069 MPa. Powder loading capacity of PEG and PW based feed stocks were found to be %55 and %61 respectively. The lowest viscosity of PEG and PW based feed stocks were found to be 304.707 Pa.s and 48.857 Pa.s respectively. Keywords: PIM, Binder, Rheological properties

Processability of different IN738LC powder batches by selective laser melting

Selective laser melting of high γ′ strengthened superalloys such as IN738LC is of huge interest for stationary gas turbine applications. In order to identify the influence of the powder characteristics on SLM processing, several batches of commercially available IN738LC powder made by gas and water atomization were characterized with respect to particle size distribution, morphology and chemical composition. The different powders were processed under equal conditions by selective laser melting (SLM) and the build quality was assessed by quantitative image analysis. Samples made out of the water atomized (WA) powder showed a higher porosity after SLM compared to the spherical gas atomized (GA) powders due to the greater irregular morphology of the powder. The porosity of the gas atomized powder batches was found to be influenced by the flow behavior of the powder. Large differences were observed for the hot cracking susceptibility of the different powder batches during SLM processing. The cracking density was correlated to the chemical composition and it was found that the minor element Si has a large influence on the SLM processability of the IN738LC powder. A strict control of this element is important to decrease the hot cracking tendency and extends the SLM processing window of this alloy.

ANCORSTEEL DWP200

Abstract Ancorsteel DWP200 is a water-atomized low apparent density powder for structural applications. The atomizing process imparts a more irregular spongy morphology to the powder particles, giving DWP200 a superior combination of green strength and compressibility compared to other atomized powders. This datasheet provides information on composition, physical properties, microstructure, tensile properties. It also includes information on powder metal forms. Filing Code: CS-192. Producer or source: Hoeganaes Corporation.

A comparative investigation on MIM418 superalloy fabricated using gas- and water-atomized powders

Gas atomized (GA) and water atomized (WA) K418 superalloy powders were injection molded, and a detail comparative investigation on microstructure and mechanical properties of MIM418 superalloys was carried out. The GA sample possesses higher sintering density than the WA sample due to its lower oxygen content, narrow pore size distribution and higher packing density. Both superalloys achieve near full dense after HIPing, and increasing HIPing temperature leads to grain growth and leaving carbide particles at the site of the original prior particle boundaries (PPBs) within the new grains. The GA powder leads to finer and more homogeneous γ′ precipitates and carbides, as well as equiaxed grains (31μm), while the WA powder results in larger γ′ precipitates with higher coarsening rate, higher concentration of PPBs, and smaller grain size (26μm). The GA sample exhibits satisfactory levels of tensile strength (1425MPa) and yield strength (1004MPa) combined with a significantly improved elongation (19.4%), which is suitable for high performance applications. The WA sample has comparable mechanical properties with that of the cast K418 superalloy, which can be used for less critical and low cost demand applications.

Drying of Water-Atomized Iron Powders

The novel drying process combines conduction and convection in cocurrent flow of the heat carrier and dried material for conductive heat and mass transfer and in countercurrent flow of the air–vapor mixture and dried material for convective heat and mass transfer. The study of heat transfer and drying kinetics allowed the optimization of the drying modes for water-atomized iron powders. The heat flux transferred by conduction through the inner wall of the drum to the dried iron powder is 3.45 · 106 W/m2 at the beginning of cocurrent flow and 0.4 · 106 W/m2 at the end. The heat consumption for drying at the optimum amount of the air supplied to the drum for convective heat transfer in countercurrent flow of 983 kg/h reduces to 415 kJ/kg compared to 511 kJ/kg at 300 kg/h. The relative specific moisture of the air–vapor mixture is 0.034–0.045 because of a large amount of dry air and high temperature, i.e., the mixture is very far from saturation and cannot condense on the dried powder.

Microstructures, mechanical properties, and fracture behaviors of metal-injection molded 17-4PH stainless steel

Metal injection molding (MIM) is a versatile technique for economically manufacturing various metal parts with complicated shapes and excellent properties. The objective of this study was to clarify the effects of powder type (water-atomized and gas-atomized powders) and various heat treatments (sintering, solutioning, H900, and H1100) on the microstructures, mechanical properties, and fracture behaviors of MIM 17-4PH stainless steels. The results showed that better mechanical properties of MIM 17-4PH can be achieved with gas-atomized powder than with water-atomized powder due mainly to the lower silicon and oxygen contents and fewer SiO2 inclusions in the steels. The presence of 10 vol% δ ferrite does not impair the UTS or elongation of MIM 17-4PH stainless steels. The δ ferrite did not fracture, even though the neighboring martensitic matrix was severely cracked. Moreover, H900 treatment produces the highest hardness and UTS, along with moderate elongation. H1100 treatment produces the best elongation, along with moderate hardness and UTS.

Effect of the Parameters of Melt Dispersion Process on the Morphology, Structure, and Particle Size of Water-Atomized Aluminum Powders

Water atomized powders of aluminum and aluminum alloys produced at a melt temperature of 690−1350°C and a water pressure of 2.0−16.0 MPa are studied. It is established that the melt temperature and the water pressure in these ranges hardly affect the shape of particles similar in size and their surface geometry. The particle size is a key parameter in the shaping and structure formation of particles. The heat transfer process occurs in film boiling conditions because of high temperature difference at 380−935°C and heat flux much higher than critical. It is established that the heat transfer coefficient at a water pressure of 10−14 MPa changes from 104 to 4 · 104 W/(m2 · °C) with a standard deviation of ±5.5% as the heat flux changes from 107 to 5 · 107 W/m2. This technique to determine the heat transfer coefficient involves the calculation of the cooling rate using the dendritic parameter, which allows increasing the accuracy of calculation.

수분사 Fe 분말의 산화물 및 이의 수소가스 환원거동

수분사 Fe 분말의 산화물 및 이의 수소가스 환원거동

Thermogravimetry study of the effectiveness of different reducing agents during sintering of Cr-prealloyed PM steels

Successful removal of the surface oxides, present on the powder particle surface, during initial stages of sintering is the prerequisite for the development of strong inter-particle necks and so high mechanical performance of the sintered PM components. In the case of water-atomized powder prealloyed with chromium, surface oxide is composed of an iron oxide layer, covering about 90–95 % of the powder surface, with some presence of more stable fine particulate oxides. Sufficiently strong inter-particle necks require as minimum full removal of the iron surface oxide layer. This can be achieved by a number of gaseous reducing agents (H2, CO, or mixture of both) as well as by carbon typically admixed in the form of graphite. The present study is focused on the analysis of the reducing ability of the different sintering atmospheres concentration of active gasses B10 vol%) as well as vacuum and their combined effect with graphite by means of thermal analysis. Number of effect characteristic for Cralloyed PM steels and their extent in different atmospheres were identified, namely risk of Cr-loss during sintering in high vacuum, risk of oxidation in CO-containing atmospheres, and nitrogen pickup, etc. When it comes to the oxidation/reduction processes, results indicate that the combination of the dry hydrogen-containing atmospheres and fine graphite grades allows successful sintering of chromium alloyed PM steels.

Oxidation of Water Atomized Metal Powders

This study focuses on the oxidation of water atomized metal powders. Pilot plant experiments were performed using liquid iron alloyed with manganese and carbon. The powder particle shape and the oxides were determined using optical and scanning electron microscopy with energy dispersive X‐ray microanalysis. The oxygen in the atomized powders was mainly present as thin surface oxide layers, which were determined to increase from 10 to 40–60 nm, at increased particle sizes from 10 to 750 μm. In addition, manganese oxides were observed to be unevenly distributed at the surface of several particles for iron powders alloyed with 0.3 mass% Mn. Experimental data indicated that between 10 and 20% of the manganese was present as oxides in the powders. However, equilibrium calculations predicted a strong driving force for oxidation of manganese. More specifically, it was estimated that only 4% of the initial manganese content remained in the final atomized powders.