Abstract: Apparatus including an electrically conductive housing, an electrically non-conducting pipe carrying the slurry through the housing, one or more primary coils each encircling the pipe within the housing and having a capacitor unit coupled thereto with a capacitor unit value chosen so that a primary coil series resonance is formed close to the value of a target magnetic resonance frequency, and for each primary coil, a drive coil and associated electrical network positioned to magnetically couple the drive coil to that primary coil. An impedance monitor coupled to each electrical network measures a complex input impedance thereof. An RF transmitter transmits a signal to one or more of the electrical networks with a frequency approximately equal to the target magnetic resonance frequency, and an RF receiver receives from each electrical network magnetic resonance signals from the target and forms an output signal of detected signals.

Abstract: An apparatus is provided for on-line detection of magnetic resonance signals from a target in a mineral slurry.

Abstract: This invention concerns the measurement of particle size of particles entrained in a gas. The apparatus (5) includes an acoustic sensor (10) used to monitor the acoustic signals produced by collisions of pneumatically conveyed particles with the sensor (10). Signal processing electronics and software (15) are used to determine, for each impact, the peak height of the acoustic signal. The particle size is calculated from the peak height distribution and either the signal (pulse) duration distribution or the airstream (impact) velocity, according to Hertzian Impact Theory.

Abstract: This invention concerns the measurement of particle size of particles entrained in a gas. The apparatus (5) includes an acoustic sensor (10) used to monitor the acoustic signals produced by collisions of pneumatically conveyed particles with the sensor (10). Signal processing electronics and software (15) are used to determine, for each impact, the peak height of the acoustic signal. The particle size is calculated from the peak height distribution and either the signal (pulse) duration distribution or the airstream (impact) velocity, according to Hertzian Impact Theory.

Abstract: In this embodiment the size distribution of particles in a fluid is determined by performing the following steps: (a) passing a plurality of ultrasonic beams through the fluid, wherein the beams have respective frequencies; (b) obtaining a velocity measure of the beams in the fluid; (c) obtaining an ultrasonic velocity spectrum as a function of particle size for the fluid; (d) determining from the attenuation of gamma-rays the density of the fluid; and (3) calculating the particle size distribution for the fluid from the velocity measure, the velocity spectrum, and the suspension density which were respectively obtained in steps (b), (c) and (d).