Abstract

Prediction of Ceramic Foams Permeability Using Ergun's Equation

Murilo D.M. Innocentini^a, Vânia R. Salvini^a, Alvaro Macedo^b,

Victor C. Pandolfellia^* * e-mail: vicpando@power.ufscar.br

^aDepartamento de Engenharia de Materiais, Universidade Federal de São Carlos, 13565-905 São Carlos - SP, Brazil

^b EMBRAPA-CNPDIA, 13560-970 São Carlos - SP, Brazil

Received: June 19, 1999; Revised: October 28, 1999

SiC-Al₂O₃ ceramic foams with 30 to 75 pores per linear inch (ppi) were used to access the application of pore size obtained by image analysis to estimate the cellular materials permeability through Ergun's equation. Samples were sliced and the pore size distribution, cross-sectional porosity and pore density were evaluated as a function of the slice thickness based on optical and X-ray computerized tomography acquired images. The average pore sizes were used to calculate permeability constants (k₁ and k₂) of Ergun's equation, which were compared to those experimentally obtained under water flow. Results indicated that the optical diameter distribution was very sensitive to the number of pore layers. Deviation between experimental and calculated values depended on the slice thickness. Nevertheless, the introduction of pore size obtained by image analysis into Ergun's equations seems to give fair results to assess the permeability of ceramic foams.

Keywords: permeability, Ergun's equation, ceramic foams, image analysis

1. Introduction

Permeability is an important parameter for the characterization of ceramic foams employed in filtration applications. Correct estimation of the pressure drop across the filter allows the filtration rate and/or the energy consumed on fluid flow to be more accurately controlled. Permeability prediction is specially useful when experimental determination must be proceeded in hostile environments, such as in the flow of molten metals. The use of reliable equations is in this case essential for the correct flow prediction and control during operation^1-3.

Forchheimer's equation has been successfully employed in the literature to predict the permeability of granular media^4-6. Such equation states that for an uncompressible fluid, the pressure drop through a rigid and homogeneous porous medium is given by:

where v_s is the fluid velocity, L is the medium thickness, m and r are the fluid viscosity and fluid density respectively, and k₁ and k₂ are constants only dependent on the medium properties, known respectively as Darcian and non-Darcian permeabilities.

Ergun⁷, in 1952, proposed expressions to describe k₁ and k₂ for packed columns made of spheres, cylinders, tablets, nodules, round sand and crushed materials (glass, coke, coal, etc.) as follows:

where e is the porosity and d_p is the mean particle diameter of the granular medium.

The major problem in the permeability evaluation of a ceramic foam is to reliably define structural properties of the cellular medium to replace the particle diameter (d_p) in Eqs. (2) and (3). Although this parameter is clearly quantified for granular media, difficulties arise when it is assumed that the web-like cellular structure made of solid filaments connected in the three dimensions has a particle diameter⁸.

Several attempts have been presented in the literature trying to replace the particle size and possibly the most obvious trial is the use of the pore or cell diameter (d_c)^9-11, which is usually determined by examining enlarged photographs of cross-sections of foam samples. Although the pores are tortuous and interconnected, with a distribution of sizes and shapes, it has been convenient in the literature to assume that d_c represents the cylindrical form of the hydraulic diameter, defined as¹²:

which gives:

where S_v is the specific surface, i.e., the total particle surface per volume of the particle.

The quantity S_v is used to define the mean particle diameter (d_p) assuming particles as spheres:

Substitution of (6) in (5) finally gives the relationship between pore and particle size for a porous medium:

Equation (7) allows to obtain an equivalent particle size for the cellular structure based on its mean pore size. Once the porosity e is quantified, Ergun's relationships (Eqs. 2 and 3) can be used to estimate the permeability constants k₁ and k₂.

While porosity is easily obtained by a water absorption test or via mass and volume calculations, the determination of pore size faces experimental problems. Since the traditional technique of mercury porosimetry is not suitable for highly-porous materials, the best alternative found has been the use of an analysis in which the cellular structure has its solid and void phases quantified through a digital image obtained in a microscope or macroviewer. Nevertheless, the lack of standard conditions for image acquisition has restrained the use of representative pore sizes into Ergun's equations, and also has been the main obstacle for reliable data comparison in the literature.

Within this context, the objective of this work was to evaluate the applicability of pore size values obtained by image analysis to predict the permeability of ceramic foams through Ergun's equations. SiC-Al₂O₃-based ceramic foams with 30 to 75 pores per linear inch (ppi) were cut in slices of different thicknesses and the average pore size obtained in each one of them was converted into equivalent particle diameter for use in Ergun's equations. The calculated permeability constants were compared with those obtained experimentally under water flow.

2. Experimental

SiC-Al₂O₃ foams containing 50 %wt alumina were produced by making ceramic replicas of open-cell polyurethane foams with 30, 45, 60 and 75 pores per linear inch (ppi)^8,13. Samples obtained were disk-like shaped ceramics with a diameter of 75 mm and 25 mm thick.

The total porosity of the samples (e_t) was calculated with basis on mass and volume measurements using the expression e_t = 1 – r_g/r_s, where r_g is the geometric density and r_s = 3.36 g/cm³ is the theoretical density of the SiC-Al₂O₃-based samples produced. The open porosity (e) was calculated by deducting from e_t the closed porosity obtained by helium picnometry.

Experimental pressure drop (DP) across each sample was measured using the apparatus schematized in Fig. 1. Permeability constants k₁ and k₂ were obtained by fitting Forchheimer's equation (Eq. 1) to experimental values of DP/L vs. water velocity (v_s). Tests were carried out in triplicate to guarantee the data repeatability.

After the permeability tests, a rectangular sample (30 x 30 x 25 mm³) was cut from the center of each ceramic foam filter using a diamond wafering saw (Isomet Buehler) with a 0.4 mm thick blade. Samples were then soaked in colorless resin (10.249 Resin and Hardener, VI Indústria & Comércio) and after hardening they were shaped and polished as disks with diameter of 30 mm and thickness of 25 mm. Each disk then was cut perpendicularly to the flow direction with the diamond wafering saw in several slices with thickness ranging from 0.15 mm to 1.7 mm. Reduction in the opacity on the slice surfaces due to sawing was accomplished by spraying mineral oil (WD-40 Company) on them. Image acquisition was performed for each slice with help of a record camera (Galai CCD Macroviewer). Illumination during acquisition was directed upwards through the slice, so that the contrast in the image produced a dark gray solid phase and a bright void fraction. The same patterns of luminance, brightness and contrast for all slices were used for the image binarization. The cross-sectional pore size distribution, pore density (number of pores per image unit area) and cross-sectional porosity (total pore area per image unit area) were obtained for each slice using the software IMAGE-PRO Plus 3.0. The image area analyzed for each slice was 238 mm² and the total number of pores acquired in each image varied between 20 and 300, depending on the pore pattern.

Average two-dimensional pore size (d_c) was statistically obtained for each pore size distribution and the mean values were converted into equivalent particle diameters (d_p) using Eq. (7). Permeability constants k₁ and k₂ were calculated using Eqs. (2) and (3).

Micrometric resolution X-ray Computerized Tomography (CT) was also used to obtain details of the pore structure¹⁴. The advantage of this technique, besides non-invasibility, is the capability of investigating inside opaque samples without the need of any special sample preparation. The CT technique is based on the principle of electromagnetic radiation attenuation by matter. When a ray beam crosses a sample, the number of photons in the direction of the beam can be attenuated following the Beer-Lambert law:

where I_o and I are respectively the incident and the emerging beam number of photons, a is the linear attenuation coefficient for the specific radiation energy in use and x is the thickness of the sample crossed by the beam. The linear attenuation coefficient is the probability per unit length of a photon to be absorbed while crossing the sample.

A micrometric X-ray CT scanner, developed at EMBRAPA Instrumentation Center, consisting of a Tungsten X-ray tube, 3 kW generator, beam width of 0.08 mm at sample center, collimator of 0.06 mm, was used for acquisition of 225 measurements of photon numbers in various directions, at chosen angles (0.8 degrees). In each direction, a scanning was made in positions separated by a constant distance (0.080 mm). This process was repeated until a scan of 180 degrees was completed. Acquired data were processed with the aid of a reconstruction software (Microvis, EMBRAPA Instrumentation Center). The total test time for each sample was 66 h 29 min for data acquisition and 4.5 min for image reconstruction. Typical sample sizes for CT analysis is 10-12 mm in diameter.

3. Results and Discussion

Table 1 shows experimental values of porosity and permeability constants obtained in this work. Open porosity was higher than 85% and varied only within a 4% range for all ceramic foams, what confirms that this parameter is not markedly dependent on the pore count⁸. Both permeability constants k₁ and k₂ decreased with the increase in the nominal pore count. An increase in the pore count implies that a larger number of pores is enclosed in the same space, with a resulting reduction in the cell volume and an increase in the number of struts (solid phase). The consequence is an increase in the viscous effects on the pressure drop due to the reduction in the flow channels area, which affects k₁, and an increase in the medium tortuosity, which intensifies the inertial effects and reduces k₂^1,3. The order of magnitude observed (10^-8 m² for k₁ and 10^-3 m for k₂) is in agreement with data presented in the literature^8-11.

Figure 2 shows the variations in the solid-void phase patterns in the captured images as the slice thickness is increased. Only three slices of each sample are pictured, representing, however, the entire range of thickness variation. Image patterns varied by two ways. Firstly, the pore size increased with the decrease in the thickness. The effect was more noticeable as the pore count decreased and reflected the reduction of cells brought to the same plane. The visualization of a structure with larger pores allowed the capture of a larger number of cells underneath the image plane, causing a virtual reduction in the pore size.

A second effect was that the pore edges became less distinct with the decrease in the slice thickness, resulting in a coalescence of pores. The consequence was an increase in the mean pore size and a reduction in the number of pores in the image plane. While the first effect was only illusory, due to the underlying struts on the same visual plane, the latter was real and points out that pore edges of ceramic foams do not fit in single planes, but are three-dimensionally connected in space. This trend was confirmed by the tomographic image in which practically all pores were interconnected. In this case, the slice thickness was 0.08 mm, being a good approximation for a two-dimension pore size distribution in the sample. The cellular geometry isotropy was verified in the very similar image patterns shown in Fig. 3, where three planes were captured using tomography in distinct depths from the same 60-ppi sample.

Although these results imply in the lack of a single value for the pore size, they reflect the complex geometry of the cellular structure and must be considered when the comparison of pore size distributions from different image analysis conditions is intended.

Figure 4 confirms that the pore diameter increased for thinner ceramic foam slices studied in this work. For the 30-ppi sample, for instance, the mean pore size was reduced from 1.28 mm for the 0.25 mm-thick slice to 0.37 mm for the 1.70 mm-thick slice. Similar effect was observed for the 45, 60 and 75 ppi samples. Such trend was confirmed in the 60-ppi sample submitted to the tomographic image acquisition, yielding a 0.8 mm mean pore diameter, which was four times larger than the pore size of a 1.20 mm-thick slice.

Figure 5 shows that the cross-sectional porosity decreased as the slice thickness increased. This implies that more strut intersections were optically brought to the same plane, reducing the passage of light through the pores and decreasing the visual void fraction. Porosity level was also reduced as the pore count increased from 30 to 75 ppi. An interesting feature is that in the tomographic image for the 60-ppi sample, which represented a situation with no optical strut intersection, the cross-sectional porosity was markedly lower (e = 0.65) than the volumetric porosity obtained via mass/volume calculations (e = 0.85). Concerning this discordant result, Liu et al.⁵ suggested that for an isotropic porous medium the porosity should be calculated as e = (A_p/A_t)^1.5 instead of the equation adopted in this work (e = A_p/A_t). A_p would be the void fraction area and A_t the total cross-sectional area used for analysis. Results in this work, however, did not validate Liu's proposal, since the porosity related to the tomographic image is further reduced to e = 0.52 when their equation is applied.

Figure 6 displays an interesting feature not visualized in the data of Figs. 4 and 5. The pore density, i.e., the number of pores per unit area, passed through a maximum as the slice thickness increased. The effect was more noticeable as the nominal pore count increased from 30 to 75 ppi. For thin slices, there was a coalescence of pores due to the lack of strut intersections in the given visualized plane. This explains the decrease in the number of pores as the slice thickness decreased. As deeper struts were brought to the same optical plane, however, new pores were optically created, increasing the pore density. Beyond a critical slice thickness, the pore density was reduced again because the pores were completely clogged by the optical intersections of struts. The explanation is related with the illumination conditions during image acquisition. When illumination is not directed through the sample, it is expected that after a critical thickness the image pattern stabilizes, because no more underneath layers are captured in the image. With illumination through the sample, as proceeded in this work, light must cross the sample to be captured and register the pore pattern. Therefore, the pore density pattern tends to darken until the total absence of pores, since further layers block the passage of light as the sample thickness increases. For the 75 ppi sample, for instance, the pore density was almost the same for the 0.25 mm and 1.25 mm thick slices, even though the optical pore diameter was completely different for both (0.94 mm and 0.11 mm respectively).

Figures 7 and 8 concern the comparison of permeability constants experimentally obtained and those calculated through Eqs. (2) and (3). It can be seen from Fig. 7 that the divergence between experimental and calculated k₁ values decreased as the nominal pore count increased. The decreasing dispersion level in the experimental values corroborated such trend. Since the permeability constants given by Ergun's equations are directly dependent on the particle size d_p, calculated from Eq. (7), d_p in this work should be higher to reach the permeability level obtained experimentally for the 30 and 45 ppi samples. Only for the 60 and 75 ppi samples the experimental k₁ value stayed within the range of calculated permeabilities. The best match for the 60 ppi sample was for the slice with thickness of 0.30 mm, which produced a mean pore size of 0.61 mm (d_p = 0.16 mm).

Similar trends were observed in Fig. 8, where experimental and calculated values of the non-Darcian permeability k₂ are plotted. In this case, however, there was a better data agreement, with exception of the 45 ppi sample, which displayed an experimental k₂ value higher than that for the 30 ppi sample. As the nominal pore count increased, the smaller optical pores became progressively more representative for using in Eq. (3). The optical pore size decreased with the slice thickness, as seen in Fig. 4, which implied that thicker samples could be used for a reliable relationship between image analysis parameters and Ergun's equations. In a general way, however, it was not possible to quantify the best slice thickness for each of the 30, 45, 60 and 75 samples studied in this work.

4. Conclusions

Results discussed in this work showed that the pore size (d_c) of ceramic foams obtained by image analysis was very sensitive to the cell layers captured by the image plane. Underlying pores in the image and the three-dimensional cellular arrangement were the main parameters that affected the pore size distribution when the sample thickness was varied. As a consequence, a single sample yielded a broad set of calculated permeabilities depending on the slice thickness analyzed.

Considering, however, that the use of Ergun's equation as originally proposed yields errors in the prediction of permeability of granular materials as high as 50%, the introduction of pore size obtained by image analysis into the same equations seems to give fair results to assess the permeability of ceramic foams. Because of the lack of standard conditions for image analysis in the literature, a reliable comparison among pore size values is only possible if similar patterns for image acquisition are used.

Acknowledgement

The authors are grateful to FAPESP, CNPq and ALCOA-Brazil for the support given to this work.

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