A chipper includes a hopper and a chipper unit. The hopper is configured to receive vegetative debris via an inlet end. The chipper unit has an outer casing and an inlet passing therethrough. The inlet of the chipper unit is connected to the outlet end of the hopper to in use receive the vegetative debris within the outer casing. The chipper unit includes a cutter located which is configured to chip vegetative debris. The hopper and the outer casing are configured so that the hopper and outer casing can be moved between a position where the hopper is substantially vertical and a position where the hopper is substantially horizontal.

The system and method of processing a used wind turbine blade provides for processing of a blade at the site of the windmill rather than transporting the blade to a processing facility. The blade may be held stationary while a cutter, such as a drum or plate with cutting teeth, is moved along a portion of the blade to shred the blade. This shredding may occur within a cutting chamber. The blade may be fed into the cutting chamber with a feeder. Smaller particles may be removed or filtered from the air within the cutting chamber and larger particles may be removed and collected in a receptacle. Portions of or the entire system may be made mobile by mounting or otherwise connecting the system to a mobile support, such as a trailer.

Embodiments according to the present invention relate to an apparatus and method for plant transportation using a smart conveyor. Embodiments of the present invention provide enhanced capabilities as a result of integrating robotic features, automations, artificial intelligence, queuing, fault control, automatic transport, scalability, safety measures, smaller footprint, and other computerized functions, along with a creative business model. In design of this invention the following high-level requirements were achieved: scalable for small, medium, and large businesses; safer than other machines in the market; sanitation consideration; simplicity in maintenance, and automated functions to reduce the need for labor (e.g., integration of robotics, AI, and/or other computerized systems).

Provided is a food waste disposer. The food waste disposer according to a concept of the disclosure includes: a housing; a grinding device positioned inside the housing and configured to grind food waste; and a storage device positioned below the grinding device and storing the grinded food waste, wherein the grinding device includes: a grinding case configured to grind the food waste, and including an outlet opening to transfer the food waste to the storage device; and a valve assembly positioned below the grinding case and opening and closing the outlet, the valve assembly being separable from the housing together with the grinding case.

The comminution device includes a feed opening for feeding material to be comminuted, a comminution shaft for comminuting the material fed to the device, and a cutting chamber, arranged between the feed opening and the comminution shaft and delimited by a cutting chamber wall, which can be pivoted.

An auto-feed paper shredder is configured for placement below the surface of a desk. The auto-feeder consists of a drawer located on the front surface of the shredder. This drawer is slid out to insert a stack of documents to be shredded. When the door is slid back into the shredder and the shredding system is activated, feed rollers draw sheets of paper either from the top or the bottom surface of the stack and feed the sheets into a conventional paper shredding mechanism. An input slot is provided to insert single sheets of paper when the auto-feeder is not being used.

A material reducing machine includes a rotary reducing drum that is rotatable about an axis of rotation and defines a reducing boundary that extends at least partially around the axis of rotation. The material reducing machine includes an infeed conveyor for transporting material to a front portion of the rotary reducing drum and defines a conveyor plane. The material reducing machine includes a mill box at least partially surrounding the rotary reducing drum and including a mill box lid mounted generally above the rotary reducing drum. The mill box lid has an inlet edge positioned above a rear portion of the rotary reducing drum and an outlet edge positioned above the front portion of the rotary reducing drum. The mill box includes an infeed opening that is configured to receive material from a feed table and has an upper opening defined by the outlet edge of the mill box lid.

The present invention relates to a method to grind mass in a grinder (1) wherein the mass is provided to the grinder (1) via a hopper (5) and transported by a feeder worm (2) to a rotating processing worm (3) which conveys the mass towards a cutting set (4) which grinds the mass and wherein the feeder worm (2) initially rotates in a first direction. During production the feeder worm (2) is periodically reversed and/or the speed of rotation of the feeder worm (2) is reduced in case the volume between the feeder worm (2) and the processing worm (3) tends to get blocked with the mass.

A machine for distributing loosefill insulation material from a package of compressed loosefill insulation material. The machine includes a chute having an inlet end and an outlet end. The inlet end receives compressed loosefill insulation material. The chute has a first portion and a second portion. The first portion forms an angle with the second portion. A shredding chamber receives the compressed loosefill insulation material from the chute. The shredding chamber forms conditioned loosefill insulation material. A discharge mechanism is configured to distribute the conditioned loosefill insulation material into an airstream. A blower provides the airstream. The angle between the first and second portions of the chute is configured to form a bend in the package of compressed loosefill insulation material. The bend in the package of compressed loosefill insulation material is configured to control the descent and direction of the loosefill insulation material entering the shredding chamber.

A machine for distributing loosefill insulation material from a package of compressed loosefill insulation material. The machine includes a chute having an inlet end and an outlet end. The inlet end receives compressed loosefill insulation material. The chute has a first portion and a second portion. The first portion forms an angle with the second portion. A shredding chamber receives the compressed loosefill insulation material from the chute. The shredding chamber forms conditioned loosefill insulation material. A discharge mechanism is configured to distribute the conditioned loosefill insulation material into an airstream. A blower provides the airstream. The angle between the first and second portions of the chute is configured to form a bend in the package of compressed loosefill insulation material. The bend in the package of compressed loosefill insulation material is configured to control the descent and direction of the loosefill insulation material entering the shredding chamber.