Abstract: The present invention relates to a geological system. The system includes an apparatus for use when scanning an uneven geological surface and that need not contact the geological surface. The apparatus includes a light source for providing light. A reflector is provided for reflecting incident light onto the geological surface, and for reflecting reflected light from the geological surface. The apparatus also includes optical fibre means for receiving the reflected light from the reflector. The system includes moving means for moving the apparatus along the uneven geological surface during scanning. Advantageously, the apparatus does not require physical sampling of material along a hole, and may instead move along the hole at very fast speeds (typically up to between 2 to 4 m/s) whilst obtaining hyperspectral radiometric data. The apparatus may be low cost, and may include no radioactive materials, so that there is little concern or business interruption if it is lost down a hole.

Abstract: The present invention relates to a geological sample scanning system to be disassembled for transport and then re-assembled onsite at a mine site or field. The system includes a stand. An imaging sensor is provided for being supported by the stand. The system also includes a transporter for transporting a geological sample, in the form of ore from the mine site or field, along a single axis to be sensed by the sensor.

Abstract: A battery pack assembly comprises a battery enclosure having a first side panel, a second side panel, a third side panel, a fourth side panel, a top panel, and a bottom panel defining a module containing volume. The battery pack assembly may contain a plurality of battery modules in the module containing volume, the plurality of battery modules having a first battery module, a second battery module, and a third battery module. The first battery module and the second battery module are positioned in a first orientation and stacked to form a column of battery modules and the third battery module is positioned in a second orientation and positioned adjacent to the column of battery modules.

Abstract: The present invention relates to a method for detecting changes in the ore grade of a rock face in near real time. The method includes the step of providing a scanning system having at least a hyperspectral imager, a position system, a LiDAR or range determination unit and computational resources. Further, the method involves determining a precise location of the scanning system utilising the position system. The rock face is scanned with the range determination unit to determine rock face position information. The method involves scanning the rock face with the hyperspectral imager to produce a corresponding rock face hyperspectral image. Further the method involves utilising the computational resources to fuse together the rock face position information and the corresponding rock face hyperspectral image to produce a rock face position and content information map of the rock face.