The cleaner assembly is configured for cleaning an automated dispensing device is described herein. The cleaner assembly includes a pallet; a plurality of side walls enclosing an inner chamber; a blower configured to propel contaminants into said inner chamber; and at least one roller operably supported by and projecting above at least one of said side walls, said at least one roller being configured to scrape contaminants off of a base plate of the automated dispensing device and towards said blower.

A dynamic, reconfigurable, and modular cleaning device utilizes software, sensors, and modular components to provide a one-size-fits-all approach to cleaning conveyor belts. The cleaning device secures to a body or frame associated with a conveyor belt, in which an associated cleaning head cleans the conveyor belt's surface. The cleaning head has an arm that extends from its body and inserts into a corresponding opening on a connecting frame associated with the cleaning device. The cleaning head is then secured in place via a cylindrical pin that extends through aligned holes on the arm and the connecting plate. Insertion of the pin connects the components together, and removal of the pin enables a user to disconnect the cleaning head and swap a new one in its place, such as to provide a different cleaning action.

This new application collects data from indoor and outdoor environments and with that data compiles databases, analyzes that data and finds relationships between pollutants, microbes, matter and diseases in humans, plants and animals. This new application is called the Artificial Intelligence Doctor. The application utilizes artificial intelligence, machine learning and parallel conveyor belts with imbedded microscope slides for the identification and analysis of microbes and matter. The application identifies microbes and matter using static electricity applied to microscope slides imbedded in conveyor belts using light microscopes, electron microscopes, polarized light microscopes, x ray machines, artificial intelligence and machine learning algorithms. The easy transfer conveyor belt system utilizes migration of microbes and microbes from drones and robots for easier identification.

This new application collects data from indoor and outdoor environments and with that data compiles databases, analyzes that data and finds relationships between pollutants, microbes, matter and diseases in humans, plants and animals. This new application is called the Artificial Intelligence Doctor. The application utilizes artificial intelligence, machine learning and parallel conveyor belts with imbedded microscope slides for the identification and analysis of microbes and matter. The application identifies microbes and matter using static electricity applied to microscope slides imbedded in conveyor belts using light microscopes, electron microscopes, polarized light microscopes, x ray machines, artificial intelligence and machine learning algorithms. The easy transfer conveyor belt system utilizes migration of microbes and microbes from drones and robots for easier identification.

A dynamic, reconfigurable, and modular cleaning device utilizes software, sensors, and modular components to provide a one-size-fits-all approach to cleaning conveyor belts. The cleaning device secures to a body or frame associated with a conveyor belt, in which an associated cleaning head cleans the conveyor belt's surface. The cleaning head has an arm that extends from its body and inserts into a corresponding opening on a connecting frame associated with the cleaning device. The cleaning head is then secured in place via a cylindrical pin that extends through aligned holes on the arm and the connecting plate. Insertion of the pin connects the components together, and removal of the pin enables a user to disconnect the cleaning head and swap a new one in its place, such as to provide a different cleaning action.

A dynamic, reconfigurable, and modular cleaning device utilizes software, sensors, and modular components to provide a one-size-fits-all approach to cleaning conveyor belts. The cleaning device secures to a body or frame associated with a conveyor belt, in which an associated cleaning head cleans the conveyor belt's surface. The cleaning head has an arm that extends from its body and inserts into a corresponding opening on a connecting frame associated with the cleaning device. The cleaning head is then secured in place via a cylindrical pin that extends through aligned holes on the arm and the connecting plate. Insertion of the pin connects the components together, and removal of the pin enables a user to disconnect the cleaning head and swap a new one in its place, such as to provide a different cleaning action.

An air-powered conveyor belt cleaner is configured with a spinner manifold with cleaning heads having nozzles that output air against a conveyor belt and an opposing catch tray assembly that catches dislodged sesame seeds and small debris or particles from the cleaned conveyor belt. A hanging bracket attaches to opposing sides of the conveyor belt’s frame and uses rollers to direct the conveyor belt in a temporarily vertical direction while the air-powered conveyor belt cleaner operates. Once the conveyor belt is vertically-oriented, plant air is directed to inlets at the spinner manifold, which is then output through nozzles perpendicularly arranged relative to the conveyor belt. The cleaning heads are adapted to rotate while operating to increase the agitation against the conveyor belt. The tips of the nozzles/tubes are bent at an obtuse angle to create a thrust caused by the output air.

An air-powered conveyor belt cleaner is configured with a spinner manifold with cleaning heads having nozzles that output air against a conveyor belt and an opposing catch tray assembly that catches dislodged sesame seeds and small debris or particles from the cleaned conveyor belt. A hanging bracket attaches to opposing sides of the conveyor belt’s frame and uses rollers to direct the conveyor belt in a temporarily vertical direction while the air-powered conveyor belt cleaner operates. Once the conveyor belt is vertically-oriented, plant air is directed to inlets at the spinner manifold, which is then output through nozzles perpendicularly arranged relative to the conveyor belt. The cleaning heads are adapted to rotate while operating to increase the agitation against the conveyor belt. The tips of the nozzles/tubes are bent at an obtuse angle to create a thrust caused by the output air.

A chain link is provided with a bushing construction where a chain pin is used for connecting a plurality of chain links, where the chain pin is inserted through the bushing along an axis, where the bushing in a cross section orthogonal to the axis has a circular cross section and where a resilient sleeve is arranged around the chain pin, where the chain pin has a flat face along the axis, and the resilient sleeve has a corresponding flat face in engagement with the flat face of the pin, and where the outer periphery of the resilient sleeve, when mounted on the chain pin, has a non-circular cross section, such that a free space is provided between the outer periphery of the sleeve and the inside of the bushing.

A chain link is provided with a bushing construction where a chain pin is used for connecting a plurality of chain links, where the chain pin is inserted through the bushing along an axis, where the bushing in a cross section orthogonal to the axis has a circular cross section and where a resilient sleeve is arranged around the chain pin, where the chain pin has a flat face along the axis, and the resilient sleeve has a corresponding flat face in engagement with the flat face of the pin, and where the outer periphery of the resilient sleeve, when mounted on the chain pin, has a non-circular cross section, such that a free space is provided between the outer periphery of the sleeve and the inside of the bushing.