Journal of Electronics Cooling and Thermal Control
Vol.3 No.2(2013), Article ID:33061,6 pages DOI:10.4236/jectc.2013.32006

Improvement of Boron Carbide Mechanical Properties in B4C-TiB2 and B4C-ZrB2 Systems

Z. D. Kovziridze, Z. Mestvirishvili, G. Tabatadze, N. S. Nizharadze, M. Mshvildadze, E. Nikoleishvili

Department of Chemical and Biological Technologies, Georgian Technical University, Tbilisi, Georgia

Email: kowsiri@gtu.ge

Copyright © 2013 Z. D. Kovziridze et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Received June 26, 2012; revised July 26, 2012; accepted August 4, 2012

Keywords: Boron Carbide; Titanium Diboride; Hot Pressing; Composite; Doping; Zirconium Diboride

ABSTRACT

Experimental works have been conducted the objective of which was to improve mechanical properties of boron carbide by introduction of doping elements into the system. Titanium and Zirconium were selected as doping elements, which were introduced into the system in the form of TiB2 and ZrB2. Four types of boron carbide-titanium and zirconium mixture with various titanium and zirconium diboride content were used in experiments. Optimal process parameters, as well as doping elements concentration, necessary to provide required high mechanical parameters in the composite were defined.

1. Introduction

Due to outstanding features of its basic component— oron, boron carbide (B4C), finds wide application in various fields, and in particular, thanks to its unique nuclear features it is widely used in control rods of nuclear power plants, as neutron absorbing material, as hard material (9.35 by Moos scale) it finds application in abrasive and finishing materials [1-3], in nozzles of sand-blasting and gas-jet facilities. Boron carbide preserves its hardness at high temperatures, which enables to use it at temperatures up to 2000˚C [4,5].

2. Main Part

However, despite its outstanding features, considered above, boron carbide, due to its fragility cannot be used as a constructive material. It is explained by its crystal structure (rhombohedral, comprising three B4C molecules [6,7] or hexagonal, comprising nine B4C molecules [5,8-14]) (see Figure 1) and strength of covalent bonds in the crystal lattice [4,15]. Besides low impact elasticity, boron carbide is characterized with low mechanical bending strength.

One of the ways to increase impact elasticity is to dope boron carbide with metal elements, which provides the growth of free electron fraction in boron carbide. In this work impact elasticity growth was achieved by introduction of titanium and zirconium diborides additives into B-C system.

3. Experimental

Samples of pure boron carbide as well as samples of containing titanium and zirconium diborides were prepared. Boron carbide powder produced by German company H.C.Stark was used in experiment. Boron carbide powder specifications are presented in Table 1.

Quantities of powders were selected in such way that

Figure 1. Crystal structure of boron carbide.

doping metal weight portion in the composite made 1%, 3% and 5% which is equivalent to 1.45, 4.35 and 7.25 wt% of titanium diboride and 2.35, 7.05 and 11.75 wt% of zirconium diboride. Fine-grained graphite, type APB, with inner surface covered with graphite foil “Sigraflex” was used for press moulds. The powders were pressed by hot pressing method in vacuum at 2150˚C - 2200˚C temperature and 20 - 25 MPa pressure, pressing duration at final temperature was 5 - 8 min.

In order to determine each property, the separate composition cylinders with dimensions Ø70 × 5.7 mm were pressed and various size samples were cut out to measure water absorption, open porosity, density, impact elasticity, thermal expansion coefficient, compressive and bending resistance. Samples surfaces were processed with fine grain diamond grinding wheel.

Density of the samples made about 96% of theoretical value. X-ray-structural analysis was done using DRON-3 diffractometer. X-ray pattern clearly shows boron carbide and titanium diboride sharply drawn peaks. Figure 2 presents diffraction patterns of boron carbide and titanium diboride, while Figures 3 and 4 present X-ray patterns of boron carbide doped with titanium and zirconnium, respectively.

Diffraction patters prove that chemical interaction of boron carbide and doping compound does not give some new phase. The material is two phased which is also proved with electron microscope research.

Figures 5 and 6 present the results of electron microscope research. Test was performed on scanning microscope SEM Cam Scan. The surfaces are not but the figures clearly show that material consists of two phases—

Table 1. Boron carbide powder specifications.

(a)(b)(c)

Figure 2. X-ray of (a) boron carbide, (b) titanium diboride and (c) zirconium diboride.

(a)(b)(c)

Figure 3. X-ray of boron carbide doped with titanium diboride: (a) 1% Ti; (b) 3% Ti; (c) 5% Ti.

(a)(b)(c)

Figure 4. X-ray of boron carbide doped with zirconium diboride: (a) 1% Zr; (b) 3% Zr; (c) 5% Zr.

boron carbide (basic phase) and doping additive. The latter is located as small inclusions at the boundaries of boron carbide grains. The patterns clearly show distinct phase boundaries and strong bonding between phases; around doping element grains the decrease of pores is observed.

Besides, the samples were tested for bending strength and compressive resistance, their thermal expansion coefficients, hardness, microhardness and impact elasticity were measured. The obtained results are presented in Table 2.

It is seen from Table 2 that when doped with titanium and zirconium diborides, mechanical properties of boron carbide increased. Especially remarkable is the increase of mechanical compressive strength and impact elasticity. The increase of impact elasticity is the main purpose of

(a)(b)(c)

Figure 5. Electron microscope patterns in B-C-Ti system; 2000-fold magnification: (a) Ti—1 wt%; (b) Ti—3 wt%; (c) Ti—5 wt%.

(a)(b)(c)

Figure 6. Electron microscope patterns of B-C-Zr system; 3000-fold magnification: (a) Zr—1 wt%; (b) Zr—3 wt%; (c) Zr—5 wt%.

Table 2. The results of samples testing.

the work. The mentioned phenomenon is presumably conditioned with the increase of free electrons’ share in boron carbide which is caused with metal solubility increase. The latter process provides the increase of elasticity preserving covalent type bonds. Only in such a case may high hardness be preserved which is clearly seen in the Table.

Figure 7 presents in diagram form the conditions and results of hardness test by Vikers method of boron carbide doped with zirconium diboride (3% Zn), while Figure 8 presents optical microscope patterns of the same sample (b) and boron carbide (a) surfaces after hardness testing. As shown in Figure 7 under 0.5 N loading indenter is implanted in material for 1.35 mcm. Test continued for 27 sec. In this case imprint form is clear, with well-defined edges (Figure 8(b)), cracks are not observed, accordingly, there happens no energy dissipation [16,17]. Here is noticed elastic property of material (Table 2) to endure loading so that not generate cracks and not turn loading energy into dissipation phenomena. The unalloyed boron carbide pressed with the same technological mode at 2150˚C is characterized with more porosity than doped one (Figure 8(a)). The imprint shows lateral cracks in right upper and lower corners. In spite of equal loading (0.5 N) the imprint form is not clear compared to the sample doped with zirconium diboride. Energy dissipation is explicit which decreased to some extent the sharpness of imprint contours.

Figure 9 presents polished and contaminated surface

(a) of boron carbide sample doped with zirconium diboride (3% Zr) and the same sample after testing for microhardness (b). The sample was contaminated with 0% water solution of NaNO3 for 15 seconds.

The figures show that matrix as well as second phase grain dimension is of micron size which is one of the preconditions of high mechanical strength. Zirconium diboride (white grains) is equally apportioned in matrix which creates dispersive strengthened composite material. This enables significant improvement of ceramic composite decomposition elasticity (Kic), also of strength (Table 2) and wear resistance.

In large grains (35 - 40 mcm, Figure 9(b)) on the whole diameter of the imprint the cracks appear. In small

Figure 7. Time ratio of loading and imprint depth (3% Zr).

(a)(b)

Figure 8. Optical microscope patters of unalloyed boron carbide and zirconium diboride doped (3% Zr) boron carbide after testing for hardness. Annealing temperature was 2150˚C.

(a)(b)

Figure 9. (a) Polished and contaminated surface of boron carbide sample doped with Zirconium diboride (3% Zr); (b) The same sample after testing for microhardness.

grains (2 - 4 mcm) cracks are not observed. The figure shows that the second phase is apportioned on matrix grain boundary, as well as, in grain (in large grain). At the same time around zirconium diboride inclusions cracks are not observed or crack avoids the inclusion which indicates that at doping the grain brittleness also decreases.

4. Conclusions

Composites B4C-TiB2 and B4C-ZrB2 with improved parameters are obtained. The above composites can be used when measuring refractory material hardness at temperatures up to 2000˚C. Besides, possibility of its application in nuclear engineering, in abrasive materials, etc. also extends.

Simultaneous increase of impact elasticity and hardness parameters provides important possibility to use this material as construction ceramics.

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