화학공학소재연구정보센터
Powder Technology, Vol.297, 34-43, 2016
Grinding of magnetite using a waterjet driven cavitation cell
This paper presents the results of an experimental study investigating the effect of stand-off distance, inlet pressure, exposure time and feed particle size on grinding of magnetite using waterjet technology. A unique experimental set-up consisting of a conventional abrasive cutting head coupled with a cavitation chamber was employed for this purpose. The results of grinding tests were evaluated based on Rosin-Rammler parameters of the products and specific energy consumption (SEC) values for generation of particles below 25 pm. A three-level experimental design for two independent variables with three center points was used to examine the effects of inlet pressure (69 MPa, 138 MPa and 207 MPa) and anvil stand-off distance (3 mm, 50 mm, 97 mm) using a feed material below 600 mu m particle size. The results showed that the anvil stand-off distance and pressure intensity are important factors for size reduction of magnetite particles. However, the effect of inlet pressure on size parameter was found higher than the stand-off distance. SEC values were found very similar for all pressure intensities tested at 3 and 50 mm anvil stand-off distance. The largest size parameter and highest SEC value were obtained using 69 MPa inlet pressure and 97 mm anvil stand-off distance. Stepwise closed circuit grinding tests were also performed operating the experimental set-up at 3 mm anvil stand-off distance and 138 MPa pressure. The size parameter of the ground products and the SEC values were found very similar after 50 s of waterjet exposure time. The feed material used in aforementioned tests was wet screened to produce mono-size fractions using a root 2 sieve series. The fractions were subjected to waterjet grinding at 3 mm anvil stand-off distance and 138 MPa inlet pressure. The largest size parameter and SEC value was obtained when the coarsest fraction (600-425 mu m) was used as feed material in these tests. The 600-425 mu m mono-size fraction has also been subjected to waterjet grinding to determine the prevailing size reduction mechanism using 3 mm stand-off distance at different pressure values. Most of the particles detected in the SEM image of the lowest inlet pressure product (69 MPa) were identified as coarse and blocky particles with sharp edges. It was found that the number of blocky particles diminished by increasing inlet pressure indicating the impact breakage conditions. It was found that the destructive breakage conditions have become prominent by increasing pressure. (C) 2016 Elsevier B.V. All rights reserved.