A method includes: storing (i) a reference image of a chute for receiving objects, and (ii) a region of interest mask corresponding to a location of the chute in a field of view of an image sensor; at a processor, controlling the image sensor to capture an image of the chute; applying an illumination adjustment to the image; selecting, at the processor, a portion of the image according to the region of interest mask; generating a detection image based on a comparison of the selected portion and the reference image; determining, based on the detection image, a fullness indicator for the chute; and providing the fullness indicator to notification system.

A method includes: storing (i) a reference image of a chute for receiving objects, and (ii) a region of interest mask corresponding to a location of the chute in a field of view of an image sensor; at a processor, controlling the image sensor to capture an image of the chute; applying an illumination adjustment to the image; selecting, at the processor, a portion of the image according to the region of interest mask; generating a detection image based on a comparison of the selected portion and the reference image; determining, based on the detection image, a fullness indicator for the chute; and providing the fullness indicator to notification system.

An unloading apparatus for horticultural products such as blueberries and the like, which are conveyed along a predefined advancement path by respective movement units includes at least one dispenser of pressurized fluid, which can be activated on command during the transit of each product in order to send a jet of the pressurized fluid toward the product and consequently cause its fall from the respective movement unit. The apparatus also includes at least one deflector screen arranged facing and proximate to the dispenser, on the opposite side with respect to the predefined trajectory in order to intercept the products struck by the jet. The screen is inclined so as to define, between its face directed toward the dispenser and a vertical plane that passes through the dispenser, a work angle one and ninety degrees configured for the optimum downward deflection of the products.

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.

A sanitary napkin disposal device. The sanitary napkin disposal device includes a housing. The housing is defined by a base, where a plurality of sidewalls extends upward from the base towards a top wall. This housing defines an interior volume. An opening extends through a sidewall of the housing and provides access to the interior volume of the housing. The opening feeds into a chute, such that items placed through the opening will fall into the chute. A door is placed over the opening, the door is movable between an open position and a closed position. The door is spring-biased in a closed position.

Embodiments herein describe a chute for temporarily buffering packages when, for example, a container disposed at the end of the chute has been removed. The chute includes a flap that activates to hold packages in an accumulation area when the container is removed. In one embodiment, the flap is disposed at an end of the chute at a decline so that during normal operation packages slide off the flap into the container. An actuator can rotate the flap from a decline position into a vertical position such that the flap serves as a stop to prevent packages from sliding off the chute when containers are being swapped out. Once a new container is disposed at the end of the chute, the actuator can rotate the flap back to the decline position so that any accumulated packages are then ejected into the container.

An additive feeder assembly includes a supply reservoir having an outlet and an outlet tube having a first end in fluid communication with the outlet and a second end located vertically higher than the supply reservoir. An air stream transports a first granular material discharged from the supply reservoir and into the first end of the outlet tube to the second end of the outlet tube. A granular material distributor is in fluid communication with the second end of the outlet tube. The granular material distributor has a top end configured for attachment to a feed supply for a second granular material, a central portion located vertically below the top end and configured to mix the first granular material and the second granular material, and a bottom end configured for vertically discharging the mixed first granular material and second granular material.

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.

Embodiments of the present disclosure describe a system for capturing dust and dust-laden air caused by the agitation, movement or transfer of particulate material. The system includes a dust collection assembly positioned proximate and associated with the delivery of particulate material to capture dust particles released by movement and settling of the particulate material when being dispensed and delivered. The dust collection assembly is positioned to direct an air flow in a flow path overlying the dust particles to capture the dust particles and move the dust particles away from the proppant thereby reducing risk of dust exposure.