A waste destruction device for sharps, needles and solid waste preferably includes a material intake member, a destruction device and a storage member. The material intake member includes an intake housing and an intake cover. The intake cover pivots from an open to a closed orientation to receive objects to be shredded. At least one microprocessor board is used to control devices of the waste destruction device. The waste destruction device preferably includes a cutter housing, a first cutter member, a second cutter member, a cutter motor and a cutter intake housing. The waste destruction device preferably contains disinfection devices for disinfecting thereof. The storage member preferably includes a storage housing, a container drawer and a waste container. The container drawer is slidably received by the storage housing.

A waste destruction device for sharps, needles and solid waste preferably includes a material intake member, a destruction device and a storage member. The material intake member includes an intake housing and an intake cover. The intake cover pivots from an open to a closed orientation to receive objects to be shredded. At least one microprocessor board is used to control devices of the waste destruction device. The waste destruction device preferably includes a cutter housing, a first cutter member, a second cutter member, a cutter motor and a cutter intake housing. The waste destruction device preferably contains disinfection devices for disinfecting thereof. The storage member preferably includes a storage housing, a container drawer and a waste container. The container drawer is slidably received by the storage housing.

A device and a method for processing feed material that has a housing, a material supply channel and a material discharge. The housing is axially divided into a first processing zone in which a rotor rotating around an axis is situated, and a second processing zone which adjoins the first processing zone in the flow direction of the feed material. In order to perform different processing procedures in one device the feed material is subject to a process gas by arranging a hollow body in the housing, coaxially to the axis for the formation of the second processing zone, which outer circumference is radially situated opposite the inner circumference of the housing, and which features at least one port at the end that is facing the rotor. A process gas, which can be fed to the feed material through at least one port, is applied to the hollow body.

An apparatus, method and system for wet or dry processing of plant material is provided. The apparatus has an enclosure attached to a frame. The apparatus includes: (a) a cylindrical rotatable drum for receiving the plant material, the rotatable drum having a plurality of slots; (b) a cutting module for cutting portions of the plant material that pass through one or more said slots; and (c) a plurality of nozzles for ejecting a liquid within the enclosure. The apparatus may further include a controller having a processing unit and a memory, the memory containing instructions for directing the processing unit. The controller may be operable to selectably control operations of the rotatable drum, the cutting module, and the plurality of nozzles. The cutting module may include a plurality of cutting reels. The cutting module and the rotatable drum may be coaxial. The cutting module may include a plurality of blades rotatable about the drum.

An apparatus, method and system for wet or dry processing of plant material is provided. The apparatus has an enclosure attached to a frame. The apparatus includes: (a) a cylindrical rotatable drum for receiving the plant material, the rotatable drum having a plurality of slots; (b) a cutting module for cutting portions of the plant material that pass through one or more said slots; and (c) a plurality of nozzles for ejecting a liquid within the enclosure. The apparatus may further include a controller having a processing unit and a memory, the memory containing instructions for directing the processing unit. The controller may be operable to selectably control operations of the rotatable drum, the cutting module, and the plurality of nozzles. The cutting module may include a plurality of cutting reels. The cutting module and the rotatable drum may be coaxial. The cutting module may include a plurality of blades rotatable about the drum.

A package reducing device includes a hopper having lap over rings, first and second main shafts which traverse the hopper, first and second pipe shafts are secured to the main shafts, where the ends of the pipe shafts are positioned interior to the lap over rings. First and second rings extend from the pipe shafts having recessed openings to position a fastener interior to the surface of the rings. Tooth plates having teeth are attached to the rings. A first motor rotates the one pipe shaft at a first rate and a second motor rotates another pipe shaft at a slower rate of rotation. The pipe shafts are rotated in an inboard direction, and the motors include variable frequency drives. The teeth reduce the size of packaging and food transported inside of the packaging during use of the invention.

A grinding blade having a blade body, a plurality of tooth mounts, a plurality of cutting teeth, and a plurality of blade stops is disclosed. The blade body has a front surface, a back surface, and a blade mounting hole along a central axis. The tooth mounts and blade stops are integral with the blade body and protrude upward and away from the back surface and the central axis. Each tooth mount has a cutting tooth releasably coupled through a tooth aperture. The blade stops and tooth mounts are equal in number and are distributed alternatingly and with radial symmetry about the central axis. A cross section of the solid of revolution defined by rotating the blade stops about the central axis overlaps with at least two thirds of a cross section of the solid of revolution defined by rotating the cutting teeth about the central axis.

A electronic grinder includes a main body and a grinding and dispensing chamber. The top of the main body open but covered by a cap. The main chamber includes a motor connected to a magnetically attached removable blade and propeller. The blade and propeller extend into the chamber when the grinder is assembled. When the cap is closed, the blade and propeller grinds material placed in the chamber and pull air down toward the blade and propeller. When the cap is opened, the blade and propeller function as a fan to generate airflow toward the top of the chamber to dispense ground material out of the chamber. The grinder can also include a microcontroller, a communications device, an infrared volume sensor, a scale, an audible buzzer, a vibration buzzer, and one or more sanitizing LED lights.

A wood chipper having a rotatable drum configured to reduce the size of wood fed into the wood chipper; a sensor configured to sense a speed of rotation of the rotatable drum; and a controller operably connected to the sensor. The controller is configured to cut power to the rotatable drum when the speed of rotation of the rotatable drum drops below a pre-set threshold value. The controller is operably engaged with a centrifugal clutch that is engaged to enable the rotatable drum to be rotated. When the speed of drum rotation drops below the threshold value because debris is slowing down rotation of the drum, the centrifugal clutch is disengaged by dropping engine speed. Disengagement of the centrifugal clutch cuts power to the drum and rotation thereof ceases so that the debris may be cleared.

The present invention relates to a method to grind meat in grinder wherein the meat is provided to the grinder via a hopper (5) and transported by a feeder worm (2) to a rotating processing worm (3) which conveys the meat towards a cutting set (4) which grinds the meat and wherein the feeder worm (2) initially rotates in a first direction. In case the feeder worm (2) is overloaded, its direction of rotation is reversed to a second direction for a certain period of time and then reversed back to the first direction.