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    For each trial, two of the sub-samples were initially sieved. Additional sub-samples were sieved if there were any significant differences in the resulting product size distributions.
    A number of comminution tests were conducted using the NCRC to determine the effects of various parameters including roll gap, roll force, feed size, and the effect of single and multi-particle feed. The roll speed was set at maximum and was not varied between trials as previous experiments had concluded that there was little effect of roll speed on product size distribution. It should be noted that the roll gap settings quoted refer to the minimum roll gap. Due to the non-cylindrical shape of the rolls, the actual roll gap will vary up to 1.7 mm above the minimum setting (ie: a roll gap selling of 1 mm actually means 1 -2.7mm roll
    gap).
    RESULTS Feed material
    The performance of all comminution equipment is dependent on the type of material being crushed. In this respect, the NCRC is no different. Softer materials crushed in the NCRC yield a lower P80 than harder materials. Figure 4 shows the product size distribution obtained when several different materials were crushed under similar conditions in the NCRC. It is interesting to note that apart from the prepared concrete samples, the P80 values obtained from the various materials were fairly consistent. These results reflect the degree of control over product size distribution that can be obtained with the NCRC.
    Multiple feed particles
    Previous trials with the NCRC were conducted using only single feed particles where there was little or no interaction between particles. Although very effective, the low throughput rates associated with this mode of comminution makes it unsuitable for practical applications. Therefore it was necessary to determine the effect that a continuous feed would have to the resulting product size distribution. In these tests, the NCRC was continuously supplied with feed to maintain a bed of material level with the top of the rolls. Figure 5 shows the effect that continuous feed to the NCRC had on the product size distribution tor the Normandy Ore. These results seem to show a slight increase in P80 with continuous (multi-particle) feed, however the shift is so small as to make it statistically insignificant. Similarly, the product size distributions would seem to indicate a larger proportion of fines for the continuously fed trial, but the actual difference is negligible. Similar trials were also conducted with the granite samples using two different roll gaps, as shown in Figure 6. Once again there was little variation between the single and multi-particle tests. Not surprisingly, the difference was even less significant at the larger roll gap, where the degree of comminution (and hence interaction between particles) is  
    As with a traditional roll crusher, the roll gap setting on the NCRC has a direct influence on the product size distribution and throughput of the crusher. Figure 7 shows the resulting product size distribution obtained when the Aurora Gold ore (mill scats) was crushed at three different roll gaps. Plotting the PSO values taken from this graph against the roll gap yields the linear relationship shown in Figure 8. As explained previously, the actual roll gap on the NCRC will vary over one revolution. This variation accounts for the difference between the specified gap setting and product PsO obtained from the crushing trials. Figure 8 also shows the effect of roll gap on throughput of the crusher and gives an indication of the crushing rates that can be obtained with the laboratory scale model NCRC.
    Roll force
    The NCRC is designed to operate with minimal interaction between particles, such that comminution is primarily achieved by fracture of particles directly between the rolls. As a consequence, the roll force only needs to be large enough to overcome the combined compressive strengths of the particles between the roll surlaces. If the roll force is not large enough then the ore particles will separate the rolls allowing oversized particles to lall through. Increasing the roll force reduces the tendency of the rolls to separate and therefore provides better control over product size. However, once a limiting roll force has been reached (which is dependent on the size and type of material being crushed) any further increase in roll force adds nothing to
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