Sintering Cycle Research Articles

Development of a powder warming compacting machine with an electrical heating system

Density control is an important factor in producing high-quality powder metallurgy parts (P/M). All mechanical properties are improved with increased density. To obtain parts with higher density, the double-pressing, double-sintering, and powder forging or copper infiltration methods are usually applied. However, the operation cost also increases from 40% to 100%. Recently, suppliers of P/M material and compacting presses have cooperated to develop warm compacting technology that increases the density of powder metal parts from 7.1 to 7.2–7.5 g/cm 3 with a single press and single sintering cycle while keeping the operation cost increase below 20%. This paper presents a new powder heating method with an electrical heater element instead of the hot oil circulation process that is currently used in warm compaction. This electrical heating system simplifies the heating element installation and can be fitted to all types of presses. This system is easy to maintain and operate, and could significantly reduce production costs.

From powders to sintered pieces: forming, transformations and sintering of nanostructured ceramic oxides

The quest to produce fully dense nanostructured ceramics has received much attention over the past 10 years. This short review highlights some of the progress made and indicates some of the avenues where further research should prove fruitful. The review concentrates mainly on the attempts to produce nanograined dense ceramics from transition aluminas, where the phase transformation into the thermodynamically stable crystallographic alpha alumina just above 1000 °C plays an important role. The review also restricts itself to traditional low pressure room temperature forming methods and sintering cycles without any applied stress. Highlights for other systems such as yttria and zirconia where dense nanograined ceramics have been successfully produced will also be described and discussed.

Spark Plasma Sintering of Alumina

A systematic study of various spark plasma sintering (SPS) parameters, namely temperature, holding time, heating rate, pressure, and pulse sequence, was conducted to investigate their effect on the densification, grain‐growth kinetics, hardness, and fracture toughness of a commercially available submicrometer‐sized Al2O3 powder. The obtained experimental data clearly show that the SPS process enhances both densification and grain growth. Thus, Al2O3 could be fully densified at a much lower temperature (1150°C), within a much shorter time (minutes), than in more conventional sintering processes. It is suggested that the densification is enhanced in the initial part of the sintering cycle by a local spark‐discharge process in the vicinity of contacting particles, and that both grain‐boundary diffusion and grain‐boundary migration are enhanced by the electrical field originating from the pulsed direct current used for heating the sample. Both the diffusion and the migration that promote the grain growth were found to be strongly dependent on temperature, implying that it is possible to retain the original fine‐grained structure in fully densified bodies by avoiding a too high sintering temperature. Hardness values in the range 21–22 GPa and fracture toughness values of 3.5 ± 0.5 MPa·m1/2 were found for the compacts containing submicrometer‐sized Al2O3 grains.

Sintering behaviour and mechanical properties of PM Al-Zn-Mg-Cu alloy containing elemental Mg additions

A commercially available PM Al-5.5Zn-2.5Mg-1.6Cu (wt-%) alloy has been used to study the effect of elemental Mg additions, ranging from 0 to 4.5 wt-%, on its sinterability and mechanical properties after sintering and heat treatment of the W and T6 type. DSC experiments were performed to study the chemical reactions occurring during sintering. Results obtained from dilatometry and DSC experiments were used to aid determination of the optimum sintering cycles under nitrogen. DSC experiments performed on as sintered samples were used for the determination of the solution treatment temperature. The microstructure obtained after sintering of the experimental Al alloys was characterised by SEM and XRD. The mechanical properties of the alloys, both, in the as sintered and heat treated states were obtained from tensile testing and hardness measurements. Additional theoretical calculations, using the THERMOCALC programme, along with the experimental observations, were carried out as an alloy design method to suggest an alternative chemical composition and alloying strategy aimed at upgrading the sintering behaviour and mechanical properties of the present alloy.

Preparation yttria-stabilized zirconia electrolyte by spark-plasma sintering

Miscellaneous sintering conditions of spark-plasma sintering (SPS) were investigated to obtain high-density yttria-stabilized zirconia (YSZ) electrolytes for solid oxide fuel cells (SOFC). Nano-size YSZ raw powder (50 nm) was densified to a relative density of 99.1% at 1400 °C, with an applied uniaxial pressure of 23 MPa, and a total of four consecutive sintering cycles at 3 min per cycle. Impedance spectroscopy was used to elucidate the electrical properties of the YSZ electrolyte. It was found that SPS could significantly improve the ionic conductivity of the YSZ electrolyte over conventional sintered (using an electrical resistance furnace) samples at similar sintering temperatures. These phenomena were due to the diverse microstructures obtained by SPS samples as compared to the conventional sintered samples. For SPS samples, most of the pores were found to exist within the grains. While for the conventional sintered sample, most of the pores were encountered at the grain boundaries, which would significantly increase the grain boundary resistance in the samples.

Densification and strength evolution in solid-state sintering Part II Strength model

A compact gains strength in sintering through low-temperature interparticle bonding, followed by further strength contributions from high-temperature densification. On the other hand, thermal softening substantially reduces a compact's strength at high temperatures. Therefore, the in situ strength during sintering is determined by the competition among interparticle neck growth, densification, and thermal softening. Distortion in sintering occurs when the compact is weak. Most strength models for sintered materials are semi-empirical relations based on the sintered fractional density. These models do not include microstructure or sintering cycle parameters; thus, they do not provide guidelines for thermal cycle design to improve compact dimensional control. A strength evolution model is derived which combines sintering theories and microstructure parameters, including interparticle neck size, solid volume fraction, and particle coordination number. The model predicts sintered strength and when combined with thermal softening gives a good prediction of in situ strength. The validity of the model is verified by comparison to experimental data for sintered and in situ strength of bronze and steel powders.

Effect of Starting Si<sub>3</sub>N<sub>4</sub> Powder Type and Sintering Conditions on the Grain Morphology of α-SiAlON Ceramics

Nitrogen rich neodymium-ytterbium containing multi-cation α-sialon starting compositions have been prepared by gas pressure sintering using conventional α-Si 3 N 4 or plasma produced β-Si 3 N 4 powder. The effect of α-SiAlON nucleation on growth mechanism was investigated by applying different sintering cycles. X-ray diffraction studies of these compositions after sintering revealed that α-sialon was observed as a matrix phase. Microstructural characterisation of the sintered materials by using α-Si 3 N 4 powder as starting composition resulted in a typical equiaxed grain morphology, as expected if the α-SiAlON nucleation step is missed out prior to growth. However, elongated α-SiAlON grains were observed by applying nucleation. In the case of β-Si 3 N 4 containing starting composition, in all cases α-SiAlON grain morphology was observed. The effects of starting Si 3 N 4 powders and different sintering conditions were discussed in detail.

Porosity effect on densification and shape distortion in liquid phase sintering

Densification and shape distortion are two important events associated with liquid phase sintering. In general, the initial porosity effects on both are ignored due to the rapid densification typical to liquid phase sintering. To completely describe the sintering process, porosity and pore size effects should be included in any sintering model. In this study, samples differing in initial porosity were sintered and quenched from various points in a sintering cycle to track the porosity effect on densification and distortion. Sinterability of the compact was defined as the ratio of sintering stress to compact strength to predict the densification and linked with sample composition and porosity. Porosity influences how the sample distorts during sintering. A high initial porosity sample is more likely to collapse along the longitudinal direction while a low initial porosity sample tends to spheroidize.

In situ strength evolution of PM compacts during sintering

The fabrication of dimensionally precise powder metal components results frequently in a trial and error approach to determine the various process parameters. Not the least of these parameters are the time and temperature profiles of the sintering cycle. These sintering variables, combined with furnace thermal gradients and component geometry are usually the key factors leading to distortion. Resistance to distortion resides in the strength of the component and it is vital therefore to know how the strength of a green compact evoives during the sintering portion of the manufacturing process. A device and a method were developed to characterize the in situ evolution of strength in response to the thermal parameters of sintering. The specific strength investigated and modeled was transverse rupture. We have used the device to characterize successfully strength evolution in various ferrous and non-ferrous alloys as well as ceramics. This work presents the results for bronze compacts and represents the first successes in modeling in situ strength evolution with respect to sintering time and temperature. The consequence of the model is to identify sintering time and temperature combinations that minimize distortion and improve dimensional tolerances.

Enhancement of heat-treatment temperature window and reduction of sintering time of Bi-2223/Ag tapes by continuous cooling sintering

In this work, Bi-2223/Ag tapes were prepared by the continuous cooling sintering (CCS) method. The results indicate that this method can dramatically extend the optimized sintering temperature window as much as 40°C. Moreover, the total sintering time can be greatly reduced. The J c of the tapes sintered for total 40 h (including first and second sintering cycles) is similar to those sintering for total 97 h without significant effect on the J c– H behavior. The mechanisms of the increase in sintering processing window and the decrease in total sintering time under the CCS process are extensively discussed.

Experimental and numerical analysis of the effects of process parameters on the properties of components in metal injection molding

*The paper mainly concerns the effects of process parameters on the final properties of components obtained by injection molding of metallic powders loaded by thermoplastic binders. The two main stages of the process are investigated. The injection stage is studied both from experiments and numerical modeling. The biphasic flow approach developed reveals well the effects of mould design and injection parameters on the final powder volume fraction distribution. The sintering stage is also investigated both from experiments and modeling. The viscoplastic like sintering model accounts well for the effect of initial powder volume fraction and sintering cycle on the final density and shrinkage of the component. Furthermore the final mechanical properties of the components obtained by metal injection molding are also investigated.

Effect of High Heating Rates on Microstructure of Alumina and Aluminum Titanate Ceramics

In conventional sintering, high heating rates are often used to enhance densification and reduce grain growth. The essence of this concept is to use fast heating rates to favor densification instead of grain growth, if the activation energy for densification is greater than that for grain growth. At low temperatures, surface diffusion is the most effective sintering mechanism but is associated with grain coarsening. Therefore, a high heating rate may take the system for densification at high temperatures before surface diffusion causes grain growth and decreases the sintering driving force. Field activated sintering technique (FAST) is a newly developed sintering method, which applies an external electrical field to enhance densification. The method applies pulsed and continuous current to powders subject to a modest pressure (< 100 MPa). Electrical current application enables fast heating rates. The sintering cycles are very short, typically less than 10 minutes for full densification.

Viscosity of WC–Co compacts during sintering

This paper describes experiments performed on WC–Co compacts in order to measure the viscosities of a Newtonian constitutive law commonly used to simulate sintering. An intermittent loading method is used during two series of experiments. The first series are dedicated to determining the axial viscosity and takes place in a loading-dilatometer. The second one takes advantage of a video-extensometry device and provides results about the viscous Poisson's ratio. The axial viscosity is obtained as a function of relative density and temperature. Viscosity shows strong exponential increase with increasing density during isothermal conditions but decreases from 10 to 1 GPa·s between 1100°C and 1325°C during a conventional sintering cycle. Viscous Poisson's ratio shows low values at low densities and increases to 0.5 at full density.

Sintering of Mo2FeB2 layered cermet containing SiC fibers

Abstract In the present investigation Mo2FeB2 based cermet (KH-C50) and its composites containing SiC fibers were sintered in two different atmospheres namely hydrogen and vacuum. It was observed that vacuum sintered samples have remarkably lower porosities than the hydrogen sintered ones. Two different sintering cycles were employed for each of the atmosphere and properties of the material were studied. Introduction of fibers in the composite imparts shrinkage anisotropy during sintering. The 2 vol.% SiC fiber-containing vacuum sintered cermets have transverse rupture strength (TRS) similar to straight cermet, but sintered at faster heating rate accompanied with a reduction stage.

Microwave reactive sintering to fully transparent aluminum oxynitride (ALON) ceramics

Aluminum oxynitride (ALON) has an approximate composition of Al23O27N5(9Al2O3·5AlN). ALON can be sintered to fully transparent ceramic material having mechanical and optical properties similar to those of sapphire with the advantages of an isotropic cubic crystal structure. The transmission range of ALON can extend from 0.2 μm in the UV through the visible to 6.0 μm in the infrared, which makes it a very useful material for many optical applications in wide range. Combined with the high strength and high hardness, ALON is an ideal material for transparent armor product [1, 2]. The conventional fabrication of transparent ALON ceramics involves using pre-synthesized ALON powder to form a green body, followed by sintering in a nitrogen atmosphere at high temperatures (>1850 ◦C) for extended period (20–100 h) [3]. A single-step preparation method was also tried to make transparent ALON ceramics, by mixing Al2O3 and AlN powders and subsequent reactive sintering at 1850 ◦C for 1 h at 3 bar nitrogen atmosphere. But the sintered body in the case was translucent [4]. Microwave sintering is a novel sintering process that is fundamentally different from the conventional sintering process. In conventional sintering, the sintering driven force, temperature, is generated by external heating elements (in resistance heating) and then is transferred to the samples via radiation, conduction and convection. In microwave process, the processing materials themselves absorb microwave power and then convert microwave energy to heat within the sample volume itself, and hence the heating is very rapid. The microwave processing of materials has major advantages of higher energy efficiency, enhanced reaction and sintering rate, cycle time and cost savings [5]. In the last four years, in this laboratory we have successfully sintered various ceramics, composites, and even powdered metals to full density using microwave processing [6, 7]. Some highly transparent ceramic samples, such as alumina, spinel, and aluminum nitride, have been successfully prepared by microwave sintering process in our lab. Compared to the conventional sintering process, the microwave sintering to highly transparent ceramic samples can be conducted at lower sintering temperatures and much shorter sintering times [8]. In our earlier work, it was demonstrated that synthesis of single phase ALON could be achieved by microwave heating at 1650 ◦C for 1 h [9]. But the density of the fired samples was only 82% of the theoretical density of ALON and they were opaque. This means that the synthesized ALON samples did not achieve full densification, even though a single phase ALON was formed. To prepare fully dense and transparent ALON samples, it needs further sintering at higher temperatures. The results in the present work showed that fully dense and highly transparent ALON ceramic samples can be made by microwave sintering at 1800 ◦C with a soaking time of 60 min at that temperature. The ALON green samples in this work were prepared by mixing high purity α-Al2O3 powder (SM8, Baikalox, Baikoski International, NC, USA) and AlN powder (Grade C, H.C. Starck, Laufenburg, Germany). The properties of the starting powders are shown in Table I. It was found that the addition of a small amount of Y2O3 increased the densification and improved the transparency of the sintered bodies during microwave sintering. Therefore the starting mixture contained 67.5 mole percent of Al2O3, 33.5 mole percent of AlN, to which 0.5% (by weight) Y2O3 in form of Y(NO3)3·6H2O was added. The powders with 3 wt.% of binder (Acryloid) were ball-milled in acetone for 24 h. After drying, the mixture was compacted uniaxially into pellets of diameter 12.7 mm and height 3 mm at a pressure of 30 MPa. Finally, the pellets were isostatically pressed at 250 MPa for 5 min. Microwave sintering was carried out by using a home-made 1.5 Kw, 2.45 GHz single mode microwave applicator in flowing pressure nitrogen at ambient pressure. The heating rate was kept around 100 ◦C/min by controlling the incident microwave power. The phase composition of the samples was examined using X-ray diffraction (XRD). The densities of the sintered ALON samples were measured by the Archimedes method. The optical microscope (Olympus) was used to study the microstructures, and the Varian spectrophotometer (CARY 2300) was used to measure the transmittance of the sintered samples. Fig. 1 shows the densification behaviors of the ALON samples during microwave sintering process. All microwave sintered samples exhibited only a pure ALON phase composition which was confirmed by XRD.

Development of cermet microstructures during sintering

Six Ti(C,N)-TiN-WC-Co cermet materials originating from the same powder mixture but sintered to different stages of the sintering cycle have been studied using scanning electron microscopy (SEM), X-ray diffraction (XRD), transmission electron microscopy (TEM), energy-dispersive X-ray analysis (EDX), electron energy-loss spectroscopy (EELS), and energy-filtered transmission electron microscopy (EFTEM). At 1350 °C, the binder phase exists both as solid and as liquid phase. The cobalt is nanocrystalline before melting, probably due to deformation during milling. A tungsten-rich inner rim starts to form and is very inhomogeneously distributed on the Ti(C,N) cores, indicating that it is difficult to nucleate the inner rim. The outer rim mainly forms at the sintering temperature and accounts for grain growth during the holding time. There are no major variations in metal content of the carbonitride phases in the materials sintered to 1350 °C or higher, although the N/(C+N) atomic ratio changes somewhat. Close to the core-rim boundary of the materials sintered at 1430 °C, there is often an enrichment of nitrogen in the core that is believed to be the result of nitrogen diffusion from the tungsten-rich rim to the titanium-rich core during cooling.

Population balance model for solid state sintering II. Grain growth

A novel population balance model based on size interval-by-size interval marching algorithm has been developed for the transient grain growth kinetics during solid state sintering. This model incorporates the coupled phenomena of densification and grain growth and exhibits reasonable capability of predicting the temporal evolution of grain size distribution for a given initial grain size distribution and time-temperature sintering cycle. In this, part II of our work, we present the coupled governing equation for sintering kinetics. We employ a size interval-by-size interval marching algorithm for the solution of the resulting population balance equation and validation of the model against experimental data for zirconia compacts sintered at 1400, 1500 and 1600°C for different times. In addition, the model has been successfully tested against published experimental data on sintering of alumina compacts.

Computer-aided control of the evolution of microstructure during sintering

Control of the microstructure is crucial for realizing optimum properties in advanced sintered materials. We describe a mathematical model for solid state sintering of ceramic systems, which is based on a population balance paradigm for pore shrinkage and grain growth. It incorporates the interplay between densification and grain growth and tracks the trajectories of pore and grain size spectra in a reasonably realistic manner. The model is employed in a simulation mode to identify the effect of initial grain (particle) size distribution and to optimize the time-temperature sintering cycle based on our own work on sintering of composite alumina-zirconia. The utility of this approach for computer-aided control of the evolution of microstructure is discussed.

On the use of trace additions of Sn to enhance sintered 2xxx series Al powder alloys

The mechanical properties of a typical sintered aluminium alloy (Al-4.4Cu-0.8Si-0.5Mg) have been improved by the simultaneous use of trace additions of Sn, high sintering temperatures and modified heat treatments. Tin increases densification, but the Sn concentration is limited to less than or equal to 0.1wt% because incipient melting occurs during solution treatment at higher Sn levels. A sintering temperature of 620 degrees C increases the liquid volume over that formed at the conventional 590 degrees C sintering temperature. However, the higher sintering temperature results in the formation of an embrittling phase which can be eliminated if solution treatment is incorporated into the sintering cycle (a modified TS heat treatment). These conditions produce a tensile strength of 375 MPa, an increase of nearly 20% over the unmodified alloy. (C) 1999 Elsevier Science S.A. All rights reserved.

Effects of intermediate deformation and thermal processing in the OPIT process upon critical current density of Ag/BiSSCO tapes

Critical current density, J/sub c/, of Ag/Bi(Pb)SCCO tapes in as-deformed and as-sintered states were studied at different stages of tape processing. Intermediate pressing and rolling result in significant I/sub c/ degradation. Non-zero I/sub c/ remains after the applications of pressing load up to 11 and 8 GPa following the third and first sintering, respectively. Under rolling conditions I/sub c/ remains non-zero up to maximum tape thickness reduction of 20%. Bending tests show that I/sub c/ reduction is the result of deformation-induced micro-crack formation which are easily healed during the first hour of the next sintering. Intermediate deformation after the first sintering cycle has been shown to accelerate significantly the 2212 to 2223 phase transformation during the first hours of the second sintering step. I/sub c/ growth during the first hour of the second sintering cycle is not connected with that phase transformation and is presumed to be the result of pinning ability and structure connectivity enhancement.