| dc.description.abstract | This study has investigated the effect of the addition of grog, which is
a pre fired material, on the thermo-physical properties and on the performance
of a kaolinite clay based refractory material as a thermal insulator.
Also assessed was a compromise between the improved thermal insulation
and the decreased strength.
The kaolinite clay refractory material has been characterized in terms
of the chemical composition, particle size distribution of the raw materials,
Young's modulus, specific heat capacrry, drying contraction of the green
samples, bulk density, apparent porosiry, water absorption and microstructure.
Mechanical testing to assess the strengths by measuring the modulus
of rapture(MOR) was also performed, which also enabled the performance
of the Weibull analysis and the calculation of the Weibull modulus. Thermal
conductivity analysis was undertaken to assess the heat insulation
abilities. Thermal shock analysis was conducted to determine the thermal
stresses the material may withstand. Thermal fatigue analysis was done
to study the growth of existing cracks. while the assessment of the stress
intensity factor enabled us to evaluate the toughness of the samples.
The thermal conductivity values were observed to increase with temperature
for samples prepared without; mixing with grog as confirmed by
theoretical calculations using both the Zumbrunnen et al and the Litovsky
et al models. The rate of increase of t~e thermal conductivity values was
observed to decrease with the increase of the percentage of the introduced
grog. For samples prepared by mixing with 50% grog, a slight decrease
of the thermal conductivity values with temperature was observed.
The critical thermal severity the samples could withstand were also
observed to improve with addition of grog to the kaolinite clay raw material.
Samples prepared without mixing with grog were observed to withstand
a thermal shock severity of about 480°C. This critical value increased
to about 500°C with the addition of 50% grog.
The R-parameters for the refractory samples were also observed to
improve when the samples were prepared by mixing with grog. The values
obtained for R, R', Rill and R"" for samples without grog were;
721.6K, 829.8"VVm-1, 3.7X10-6 Pa and 3.3X10-5 N2m-3 respectively,
while for samples with 50% grog the values were; 743.5K, 835.7Wm-1
,
3.9X10-6 Pa and 3.5X10-5 N2m -3 respectively.
The fatigue life, which is the number of thermal cycles N the material
can go through before developing catastrophic cracks was studied by thermal
fatigue analysis measurements. Values measured for the slow crack
growth parameter n and the Weibull modulus m, showed improvement
on crack growth resistance with introduction of grog to the refractory material.
For samples prepared without mixing with grog, values obtained for
m and n were 29.5 and 19.5 respectively. For samples prepared by mixing
with 50% grog, the values for mand n were 30.5 and 29.5 respectively.
The critical stress intensity factor K1c values measured for samples
without and with 50% grog also indicated some improvement on the
toughness of the refractories on addition of grog to the material. The
values ranged between 1.45MPam1/2 and 2.3MPam1/2 for firing temperatures
between 600°C and 1;250°C for samples without grog. For samples
with 50% grog in the same firing temperature range, the K1c values
ranged between 1.6M Pam 1/2 and 2.6M Pam 1/2 .
In all these cases, the addition of grog was observed to improve the
properties of the refractory material. There was improved toughness, thermal
shock resistance, crack growth resistance, rate of increase of thermal
conductivity with temperature and improved thermal fatigue resistance. | en |
