The compression process is one of the more widely used industrial manufacturing methods for fabricating desired shape of specimens with various materials such as metals and ceramics. In the compaction process, the upper punch moves into the powder, and force is transmitted between particles, then achieving densification. In this process, the powder can be considered to be in a particulate state, which means that while the powder consists of solids, it has characteristics quite similar to the fluid. Therefore, particles in the process can be seen as responding to hydrostatic pressure, and it can be assumed that the pressure is constant. However, the forces acted on the inter-particle continue to change during the process. Many parameters affect the force change, including compaction speed and the contact angle between particles. However, it is very difficult to verify these effects through experiments because it is impossible to arrange the inter-particle angle. Therefore, in this study, the force transmission mechanism was simulated in the compaction process using FEM simulation. To examine the contact angle and force transmission between the particles, a green compact was modeled as individual particles rather than as a continuum green compact. Finally, it was confirmed through analysis that the pressure transmission between the particles remained constant during the compression process.11Ysciescopu

BAEK, JONG WON

PARK, SEONG JIN

Korean Journal of Metals and Materials

English

포항공과대학교

[Research Paper] 대한금속 ·재료학회지 (Korean J. Met. Mater.), Vol. 57, No. 2 (2019) pp.115-123DOI: 10.3365/KJMM.2019.57.2.115Pressure Transmission in the Compaction Process of Nickel Powder Using the Finite Element MethodsJong Won Baek and Seong Jin Park*Department of Mechanical Engineering, Pohang University of Science and Technology (POSTECH), Pohang 37673, Republic of KoreaAbstract: The compression process is one of the more widely used industrial manufacturing methods forfabricating desired shape of specimens with various materials such as metals and ceramics. In the compactionprocess, the upper punch moves into the powder, and force is transmitted between particles, then achievingdensification. In this process, the powder can be considered to be in a particulate state, which means thatwhile the powder consists of solids, it has characteristics quite similar to the fluid. Therefore, particles in theprocess can be seen as responding to hydrostatic pressure, and it can be assumed that the pressure is constant.However, the forces acted on the inter-particle continue to change during the process. Many parameters affectthe force change, including compaction speed and the contact angle between particles. However, it is verydifficult to verify these effects through experiments because it is impossible to arrange the inter-particle angle.Therefore, in this study, the force transmission mechanism was simulated in the compaction process usingFEM simulation. To examine the contact angle and force transmission between the particles, a green compactwas modeled as individual particles rather than as a continuum green compact. Finally, it was confirmedthrough analysis that the pressure transmission between the particles remained constant during thecompression process.(Received December 17, 2018; Accepted December 24, 2018)Keywords: compaction, FEM simulation, spherical powder, pressure transmission1. INTRODUCTIONThe Powder Metallurgy (PM) process is one of the morewidely used methods for manufacturing complex parts inindustry. The advantages of this manufacturing technique isthat it minimizes material loss and weight [1]. The overallprocedure of PM process is as shown in Fig. 1.The first stage of the PM process is mixing to prepare acompound powder with an additive material such as alubricant. Before mixing, sieving process is conducted toobtain the desired powder size. Next, a compaction process iscarried out to manufacture green compacts with a desiredshape. Finally, the green compacts are densified in a sinteringstage at high temperature. In the compaction stage, the finalpressure (compaction load) is determined, but the forcechanges continuously during the process. The force change isinfluenced by the contact angle between the powder andvarious other conditions. However, it is very hard todetermine pressure changes using compaction experiments,because it is impossible to measure the contact angle andcontact area. In this case, FEM simulation is a very usefulmethod for examining pressure transmission during thecompaction process.Most prior studies have focused on optimizing thecompaction process conditions and geometries to obtain fulldensity [2-10]. Kwon et al. [11] and Lee et al. [12] carriedout simulations on a powder compaction process for complexshapes such as automobile parts, to predict their densities.Also, FEM has been widely used to examine the compactionbehavior of metal/ceramic materials [13-18]. However, thepowders were considered to be continuum (bulk) greencompacts, so particle-particle interaction was not modelled. The ‘particulate state’ of matter is peculiar. Powdersconsist of solid particles yet exhibit fluid-like characteristics.- 백종원: 박사, 박성진: 교수*Corresponding Author: Seong Jin Park[Tel: +82-54-279-2182, E-mail: sjpark87@postech.ac.kr]Copyright ⓒ The Korean Institute of Metals and Materials116 대한금속 ·재료학회지 제57권 제2호 (2019년 2월)They assume the shape of the vessel into which they are‘poured’ and are ‘compressible’. The consolidation ofpowders necessarily involves the transmission of pressurethrough inter-particle contacts. There are reasons to believethat constrained powders transmit pressure in much the sameway that confined liquids do. When a powder is subjected to isostatic pressing, its linearshrinkage is equal in all directions independent of the particleshape and size distribution. The obtained compact hasuniform density throughout its body. During the die-compaction of a powder, the pressure-dependence ofdensification is close to that obtained during isostaticpressing. In the absence of pressure losses, which are mainlydue to die-wall friction, one can expect the pressure-densityrelation to be independent of the mode of compaction. Evenunder conditions of unidirectional compaction, the poresretain their shape to a large extent [19]. During sintering, thepowder compact undergoes isotropic shrinkage whileretaining of its external shape as if it were subjected toisostatic pressing.Thus, whether pressure is applied externally (compaction)or derived from within (sintering), it can be assumed that ahydrostatic stress state prevails during powder consolidationthat is independent of the particle shape and size distribution. As applied to the compaction of a powder consisting ofspherical particles of unequal sizes, Equation (1) reads asfollows:(1)where  is the compaction pressure;  is the pressureacting over the surface of a particle of radius a ; and  is thetotal load transferred to the particle [20-23]. If the particlesare of the same size, each one of them must carry equal loadindependent of the number of nearest neighbors(coordination number):(2)In contrast to liquids, metal powders keep a permanentrecord of their response to the applied pressure because oftheir ability to deform plastically. During compaction of ametal powder, each particle attempts to indent its neighborsand, as a result, the inter-particle contacts are converted intocontact flats. At a given pressure, the extent of flattening(total contact area) of each particle depends on the inherentresistance of the material of the particles to indentation(hardness) and the total load transferred to it. Thus,measuring the total contact area of the individual particles ofa compacted metal powder makes physical verification ofequation (1) and (2) possible.In this study, FEM simulation were conducted to examinethe pressure transmission (force transmission) during thecompaction process. The nickel particles and cylinder diewere modelled by using the ABAQUS 6.13 tool. Thesimulation results were verified by comparison experimentalresults. The relationships between particle arrangement anglewhich affect the contact area, compaction speed, and contactforce were obtained. 2. SIMULATION CONDITIONSFigure 2 shows the initial configuration of the simulation.A total of 9 particles were modeled and located in thecylinder shape die. Vertical speed was applied at the top ofthe die, while the bottom surface is stationary and rigid.PaPp1Pp2… Ppnlp12πa12⁄= = = = =lp22πa22⁄= … lpn2πan2⁄= =PaPplpPalp2πa2⁄=Fig. 1. Overall procedure of PM processJong Won Baek and Seong Jin Park 117Because it does not move and it is not deformed by the upperpunch moving.The particles were Nickel powder provided by POSCO.Experiments to investigate mechanical properties of elasticityand plasticity were also carried out and the results aresummarized in Table 1.Also, the boundary conditions were determined as shownin Table 2, to examine the force-displacement relationshipand force-contact surface in relation to compaction speed anddifferent particle arrangement angles. The compaction speed was set to 50, 100, 200 mm/s andthe particle arrangement angles were chosen to be 0, 22.5, 45degrees. Figure 3 demonstrates the modeling of the particlearrangement angles.In this simulation, the equation of equilibrium was appliedas below:(3)where,  is a stress,  is a body force. Also, stress-strainrelationship in elastic (Hooke’s law) was determined asbelow:(4)The plastic strain rate tensor of the metal powder is definedas follows: (5)σij j,fi+ 0=σ fiσ Eε=ε·ijpλ∂Φ∂σij--------=Fig. 2. Initial geometry of the compaction simulationTable 1. Material properties of slab heater cover partsElasticity PlasticityDensity(g/cm3)Young’s modulus(GPa)Poisson’sratioYield stress(MPa)Plasticstrain7.85 200 0.31185 0290 0.05345 0.1388 0.15413 0.2434 0.25Fig. 3. Particle arrangement anglesTable 2. Boundary conditionsBoundary conditionBottom FixParticle arrangement angles 0°, 22.5°, 45°Compaction speed 50 mm/s 100 mm/s 200 mm/s118 대한금속 ·재료학회지 제57권 제2호 (2019년 2월)where,  and  are a yield function and the scalar value ofthe powder material, respectively. The rate of change of therelative density can be written as follows from the massinvariant relation. (6)Finally, the plastic yielding behavior of the powder can bedefined by the Shima-Oyane equation as follows [24].(7)where, q and p are the effective stress and hydrostaticpressure, respectively.4. RESULTS AND DISCUSSION4.1. Simulation verificationA compaction experiment was conducted to verify thesimulation. The compaction speed was set to 100mm/s withpressure from 20 MPa to 180 MPa increasing in 20 MPasteps (a total 9 data points were obtained). Initially, theparticle arrangement degree was 0° to represent the idealcase. Figure 4 shows the initial/final configuration of thesimulation. ABAQUS 6.13 was used in this research with an8-noded solid element, C3D8, with distortion, hourglassmode control. Reduced integration was applied to decreasethe computational cost. A total of 102,536 elements weregenerated with an average aspect ratio of 1.05.As shown in Fig. 4, the results confirmed that the contactlength between the particles or die gradually increased duringcompaction. A ductile sphere subjected to free-compressionunder a load  undergoes deformation at the points ofcontact with the flat surfaces forming two circular contacts ofequal radius  (refer to Fig. 5). The mean contact pressure  is given by (8)where  is the total contact area of the sphere. Notethat the mean contact pressure does not depend on the spheresize. Neglecting the deformation-induced increase in thesurface area of the sphere, Eq. (8) can be rewritten as(9)where a is the radius of the sphere;  is thedimensionless relative contact area of the sphere; and is its original surface area. Equation (9) suggeststhat the pressure is applied over the surface of the freelycompressed sphere . Evidently, this pressure-termis independent of the material of the sphere.Φ λ·D·Dε·kkp–=Φ σ εmp–D, ,( )qσm-----⎝ ⎠⎛ ⎞22.4921 D–( )1.028pσm-----⎝ ⎠⎛ ⎞2D5–+ 0= =lfxfpmpmlfπxf22lfsc⁄=⁄=sc2πxf2=lf2πa2 pmsr= =srscso⁄=so4πa2=pflf2πa2⁄=Fig. 4. Compaction simulation at (a) initial configuration, (b) halftime configuration, and (c) final configurationJong Won Baek and Seong Jin Park 119Figure 6 shows the plot of relative density versuspressure for comparison. Comparing the experimentaland simulation results (Fig. 6), the maximum error waswithin 2.5%, and the average error within 1.2%.Therefore, the simulation was verified.4.2. Force/displacement and contact surfacearea relationship with different compactionspeedIn order to study the effect of compaction speed,simulations were conducted of the force-displacement andforce-contact surface area with 0°, 22.5°, and 45° particlearrangement angles. Figure 7 shows the force-displacementrelationship with constant angles and different compactionspeed.In 0° and 22.5° case, the force increases almost linearlyat 0.11 mm displacement. After that point (0.11 mm), theslope changes abruptly. This is caused by a change incontact area. In other words, the particles at the upper partand lower part were not in contact with each other until thedisplacement reached 0.11 mm. Therefore, the forceincreased rapidly. However, as the velocity changed, therewas no significant difference observed. Even if theparticles contact each other, the rate of increase in contactsurface is not sufficiently large [9].According to the force-contact surface area plot for allcases, force increases linearly at the transition point (inter-particle contact point). After that, force also increases but thegradient changes. Physically, the gradient (slope) is thepressure (force / area) [25-27]. It can be seen that the forceis transmitted while the pressure is kept constant, and thecompaction process proceeds with constant pressure evenafter the particles come into contact with each other [28,29].Also, as the particle rearrangement angle increases, thecontact points between the particles gradually move awayfrom the center. Therefore, the point of contact is graduallydelayed (the details are shown in Fig. 9).4.3. Force/displacement and contact surfacearea relationship with different particle arrangementanglesWhen the particle arrangement angle is changed, it can beseen that a difference in force is caused by the difference incontact area. Until the particles come into contact with eachother, force increases with almost the same slope, but theincrease in force after contact is different. Specifically, eventhough the force transmission among the particles is differentwith constant pressure applied, pressure was constantlytransmitted considering the contact surface area and force.However, the point of force increase was uniqued for eachcase due to the particle contact angle, as shown in Fig. 9 (a)and (b)As shown in Fig. 9, when the particle arrangement anglewas 22.5 degrees, the powder above contacted one powderlocated below. However, when the powder was placed at 45degrees, the powder only contacted 2 particles. Thisindicates, that when the powder is arranged at 45 degrees, therepulsive force between the powder after contact increases,the pressure increases and the force is transmitted comparedto the case of 22.5 degrees. In addition, as shown in Fig. 9Fig. 5. compression of a ductile sphereFig. 6. Pressure-relative density plot for comparing experimentaland simulation results120 대한금속 ·재료학회지 제57권 제2호 (2019년 2월)(a), an asymmetry in the contact between the powdersappears when they are arranged at 22.5 degrees. This cancause problems, since the powder will be deformed unevenlyduring the powder compaction process and finally the densitydistribution will not be uniform.5. CONCLUSIONAn analysis of the pressure transmission phenomenon basedon compaction speed and powder arrangement angle wascarried out during the powder compaction process. First, toverify the developed analysis program, compressibility curveFig. 7. Force-displacement and force-contact surface area plots with (a) 0°, (b) 22.5°, and (c) 45° Jong Won Baek and Seong Jin Park 121were derived through compression process experiments andanalyzed under the same condition. As a result, it showed anerror of 2.5% or less. The force-displacement, and force-contact area were derived with different compaction speeds.As the compaction speed increased with the same particlearrangement angle, there was no significant difference in thechange of force. However, it was confirmed that the point atwhich the force increases in relation to the particlearrangement angle changes at the same compaction speed.The gradient of all force-contact surface areas remainedconstant before and after contact. Physically, gradient meanspressure in the force-area curve, and the pressure transmissionFig. 8. Force-displacement and force-contact surface area plots with (a) 50 mm/s, (b) 100 mm/s, and (c) 200 mm/s 122 대한금속 ·재료학회지 제57권 제2호 (2019년 2월)between particles remains constant as the compaction processprogresses. In other words, the force increases, but the contactarea also increases accordingly, so it can be seen that thepressure stays constant. The conclusions of this paper aresummarized below:A compaction simulation was conducted at the particlelevel by using FEM and it determined the relationshipbetween force-displacement / contact surface area.It was demonstrated that compaction speed, stacking, andthe changes occurring in particle coordination during thecourse of consolidation had no effect on the uniformity ofpressure distribution in the powders, and consequently, on theprogress of consolidation. ACKNOWLEDGEMENTThis work was supported by the Industrial TechnologyInnovation Program(No. 10048358) funded by the MinistryOf Trade, Industry & Energy(MI, Korea)REFERENCES1. J. H. 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Pressure Transmission in the Compaction Process for Nickel Powder using Finite Element Methods

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Pressure Transmission in the Compaction Process for Nickel Powder using Finite Element Methods

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