A system for handling particulate material includes a chute. The chute includes a main conduit and first and second branch conduits that extend from the main conduit. The chute includes a flow adjuster configured to alter a flow distribution of the particulate material between the first and second branch conduits. In an example operation, first and second containers are placed onto a shuttle on a transfer conveyor. The transfer conveyor moves the shuttle with the first and second containers beneath the chute to place the first container under the first branch conduit and the second container under the second branch conduit. The containers are loaded with particulate material distributed through the chute. Then the containers are moved away from the chute.

A chute tube for facilitating particle transfer and distribution. The chute tube for transferring particles has a charging chute tube with a charge inlet of particles, a discharging chute tube and an intermediate chute tube slantingly connected between the charging chute tube and the discharging chute tube. The intermediate chute tube includes a groove without steps formed by a combination of a first inclined surface and a second inclined surface, and the groove is of a cross-sectional shape corresponding to two adjacent sides of a triangle.

A flume for supplying vegetable pieces in a supply of liquid, the flume extending between a flume inlet and a flume outlet, the flume comprising: a gulley section having an upstream inlet end at the flume inlet and a downstream outlet end, the gulley section having opposed sidewalls and a gulley floor therebetween, and a spreader section having opposed first and second lateral walls and a spreader floor therebetween, the spreader section having an upstream end connected to the downstream outlet end of the gulley section, the spreader section progressively increasing in width between the opposed first and second lateral walls in a downstream direction from the upstream end to a downstream end of the spreader section, wherein the opposed first and second lateral walls are each outwardly inclined away from a longitudinal axis of the spreader section by a respective angle α° for the first lateral wall and β° for the second lateral wall, in respective opposite directions, which extends from the upstream end of the spreader section to the downstream end of the spreader section, wherein the gulley section has a width of the gulley floor at the downstream outlet end of W1, the length of the spreader section between the upstream and downstream ends of the spreader section is N, and the dimensionless ratio N/W1 is within the range of from 2 to 15, and wherein the sum of α° and β° is from 10 to 25°.

A pulse cleaning system for disinfecting untreated grains and pulses. The pulse cleaning system comprises an outer body, a top end, a top outer edge, a bottom end, and a conveyor. The pulse cleaning system is useful in cleaning a dry commodity by inserting the dry commodity into the top end, cleaning the dry commodity within the outer body, releasing the dry commodity at the bottom end, and collecting the dry commodity on the conveyor. The outer body comprises a top opening at the top end, and a bottom opening at the bottom end. each among one or more exterior burner assemblies and an interior chamber strip burner is configured to create variable flame according to an end user's preference, or according to amounts of a fuel provided. after treatment by the pulse cleaning system, the dry commodity is referred to as a treated grains and pulses.

A system and method for sizing and separating granular particles within the bulk granular solids by creating a graded granular flow comprising multiple sized fractions with gradation of the particles according to particle size between relatively fine fractions and relatively coarse fractions; and capturing at least a portion of granular flow. The system (11) comprises means (25) for creating the graded granular flow, and means (30) for capturing at least a portion of the graded granular flow. The graded granular flow is split into separate streams, one of which is subsequently captured by intercepting that stream. The intercepted stream may be collected or redirected for further processing.

1. —It is disclosed an autonomous monitoring system based on a magnetic field variation: (a) that allows (i) predicting wear, failures and cracks in mining equipment; (ii) prevent and detect, in real time, uncrushable material such as metal and/or material from “old mining” or past operations and/or parts or pieces of mining equipment; (b) to be used/installed in mining and/or loading equipment, such as, but not limited to, cables shovel, hydraulic shovel, a loader or other type of loader; (c) that allows detecting strange metal bodies, and also, knowing the level of wear and/or detecting a failure or fracture in the parts of these equipment almost immediately, particularly, but not limited to, the teeth or part of them, preventing unscheduled stops and accidents of the personnel, and improving effectiveness and efficiency in the planning of predictive and preventative maintenance operations; 2.—an installation method of the system. 3.—an operating method of the system. 4.—tooth, ground engaging tool or part of a mining and/or loading equipment, which comprises one or more monitoring devices.

A system and method for separating granular particles according to particle size, and more particularly enhance ore grades by removing unwanted material. The system (10) comprises means (11) for transporting granular material (12) comprising multiple sized fractions with gradation of the particles according to particle size between relatively fine fractions and relatively coarse fractions, in a direction having a horizontal component; and subjecting the granular material (12) to vibration while being so transported to induce some separation of particles according to particle size. The system (10) further comprises means (13) for causing the granular material (12) to subsequently move as a granular flow (14) along a curved path (15) under the influence of gravity to further induce separation of particles according to particle size. The system (10) still further comprises means (16) for dividing the granular flow (14) moving along the curved path (15) into different streams (17) according to their trajectory.

Disclosed is a blast furnace apparatus includes: a rotating chute; a profile measurement device configured to measure surface profiles of a burden charged into the furnace; and a tilt angle controller configured to control a tilt angle of the chute, in which the device includes a radio wave distance meter installed on the furnace top and configured to measure the distance to the surface of the burden, derives the profiles on a basis of distance data for the entire furnace obtained by scanning a detection wave of the distance meter in the furnace in a circumferential direction, and includes at least one of arithmetic units configured to command during rotation, on a basis of the surface profiles obtained, the controller to change the tilt angle of the chute, or a controller to change a rotational speed of the chute or a feed speed of the burden fed to the chute.

A compact modular mobile aggregate processing system configured with no stand-alone inter-plant conveyors for decreasing the footprint of the system and an infinitely adjustable flow diverter(s) for increasing the control of and variation of output characteristics of the system; the system further including specialized folding conveyors.

A conveyor used with a harvester such as a wind rower has a chute at its discharge end with a deflection surface which controls the throw trajectory and thus the throw range of crop being cut. The orientation angle of the deflection surface relatively to the conveyor may be varied as a function of the particular crop throw characteristics to change the throw range of the conveyor as needed to form merged windrows of a particular crop while avoiding windrow widths which are too wide for efficient harvesting.