A wet mixing process
is proposed for filled rubber composites with
a high silica loading to overcome the drawbacks of high energy consumption
and workplace contamination of the conventional dry mixing process.
Ball milling was adopted for preparing the silica dispersion because
it has a simple structure, is easy to operate, and is a low-cost process
that can be easily scaled up for industrial production. The response
surface methodology was used to optimize the making of the silica
dispersion. The optimum conditions for a well-dispersed silica suspension
with the smallest silica particle size of 4.9 mm were an about 22%
silica content and 62 h of ball milling. The effects of dry and wet
mixing methods on the properties of silica-filled rubber composites
were investigated in a broad range of silica levels from low to high
loadings. The mixing method choice had little impact on the properties
of rubber composites with low silica loadings. The silica-filled rubber
demonstrated in this study, however, shows superior characteristics
over the rubber composite prepared with conventional dry mixing, particularly
with high silica loadings. When compared to silica-filled natural
rubbers prepared by dry mixing (dry silica rubber, DSR), the wet mixing
(for WSR) produced smaller silica aggregates with better dispersion.
Due to the shorter heat history, the WSR exhibits superior curing
characteristics such as a longer scorch time (2.2–3.3 min for
WSR and 1.0–2.1 min for DSR) and curing time (4.1–4.5
min for WSR and 2.2–3.1 min for DSR). Additionally, the WSR
has superior mechanical properties (hardness, modulus, tensile strength,
and especially the elongation at break (420–680% for WSR and
360–620% DSR)) over the DSR. The rolling resistance of WSR
is lower than that of DSR. However, the reversed trend on the wet
skid resistance is observed.
Abstract. Under the 20122050, the International Energy Agency (IEA) and the World Business Council for Sustainable Development (WBCSD) have developed a roadmap for the reduction of energy and carbon intensities in cement production. The aim of this research is to study and evaluate the energy consumption (EN), global warming potential (GWP) impact, and economic assessment of Portland cement production. It was found that the total EN and GWP of conventional process were 3.29 GJ per ton of Portland cement and 0.76 ton CO2 equivalent per ton of Portland cement, respectively. The total cost was 1,346 THB per ton of Portland cement. The largest contribution was from fossil fuels used and the limestone calcination in clinker production which produced the total EN of 83.63% and the total GWP of 91.36%, and the total cost of 63%. In addition, the production of Portland cement was environmentally improved by using low carbon fuels, increasing of alternative fuels to fossil fuels ratio, and increasing of pozzolan to cement ratio. The results showed that all improvements significantly reduce the total EN, GWP, and the total cost. When the using of low carbon fuels, the increasing of alternative fuels to fossil fuels ratio, and the increasing of pozzolan to cement ratio, the EN, GWP, and the total cost were decreased by 1.68%, 18.33%, and 4.39% of the total EN and by 25.35%, 3.06%, and 10.45% of the total GWP, and by 4.6%, 4.12%, and 10.64% of the total cost, respectively.
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