The disclosure extends to apparatuses, methods, and systems, for producing frozen confections and conditioning ice for use in frozen confections. A frozen confection machine includes a hopper portion for receiving ice into an interior, and a motor configured to rotate a drive shaft, a blade to condition the ice in the hopper during rotation of the motor. The frozen confection machine also includes a lid for selectively covering the interior of the hopper, a bias member for biasing the lid away from a closed position, and a switch for causing the motor to actuate in response to the lid being pressed to a closed position.

The disclosure extends to apparatuses, methods, and systems, for producing frozen confections and conditioning ice for use in frozen confections. A frozen confection machine includes a hopper portion for receiving ice into an interior, and a motor configured to rotate a drive shaft, a blade to condition the ice in the hopper during rotation of the motor. The frozen confection machine also includes a lid for selectively covering the interior of the hopper, a bias member for biasing the lid away from a closed position, and a switch for causing the motor to actuate in response to the lid being pressed to a closed position.

The disclosure extends to apparatuses, methods, and systems, for producing frozen confections and conditioning ice for use in frozen confections. A frozen confection machine includes a hopper portion for receiving ice into an interior, and a motor configured to rotate a drive shaft, a blade to condition the ice in the hopper during rotation of the motor. The frozen confection machine also includes a lid for selectively covering the interior of the hopper, a bias member for biasing the lid away from a closed position, and a switch for causing the motor to actuate in response to the lid being pressed to a closed position.

A soap remnant recycling assembly includes a housing that has a bottom wall, a top wall and a perimeter wall extending therebetween. The top wall has an opening extending therein and into an interior of the housing. A conduit is attached to the top wall and is in fluid communication with the opening. A funnel is attached to the conduit and extends upwardly therefrom. An access aperture extends through the perimeter wall and into the interior. A door is removably positioned in a closed position closing the access aperture or in an open position. A spindle is positioned within the conduit. The spindle has a plurality of blades attached thereto. A plate is mounted within the housing. The plate is movable toward or away from the door. The plate extends from the top wall to the bottom wall and from a first lateral wall to a second lateral wall.

A novel safe paper feed opening structure of a paper shredder, having a shredder upper cover and a paper shredder plate. The shredder upper cover has an opening, and the paper shredder plate is at the opening. The opening communicates with a moveable feed throat. The paper shredder plate can be configured in one of four positions. The moveable feed throat has a normal opening and a wide opening. The feed throat can be moved to the wide opening when the shredder plate is in a JAM CLEAR/OFF position. The CLOSED/OFF, NORMAL/ON, and SHRED-SAFE/OFF positions use a normal feed throat. A method for operating a paper shredder includes providing a shredder upper cover; providing the shredder upper cover with an opening; disposing a paper shredder plate at the opening; disposing the opening in communication with a moveable feed throat; and moving the feed throat responsive to a paper shredder condition.

An apparatus for shredding meat with a hopper and a frame. The hopper has upper and lower rotor assemblies mounted to rotate horizontally within a shredding region. Each rotor assembly is composed of an arbor and fingers arranged in paraxial rows around the arbor. Four rows of pegs extend horizontally into the shredding region. A front row and a back row are each 0.75 inch above and below, respectively, the upper rotor assembly. A back row and a front row are each 0.75 inch above and below, respectively the lower rotor assembly. The hopper is suspended in the frame, which houses the drive mechanism that rotates the rotor assemblies in opposite directions. The upper rotor assembly pushes product dropped into the shredding region into the upper back row to shred the product. The lower rotor assembly pushes the shredded product into the lower front row to further shred the product.

Granulator mill (1) comprising a frame (10), a cutter housing (20) with a granule chamber (22) comprising at least one non-rotatable blade (24) inside the granule chamber (22), and further comprising a rotatable rotor (30) arranged inside the granule chamber (22). The rotor (30) comprises blades (32, 34) which are arranged for cooperation with the non-rotatable blade (24) for granulating waste material to granules. A normal (n) to a first opening (26a) of the granule chamber (22) is pointing substantially vertically upwards in the normal position of use of said granulator mill (1), and characterising is that the cutter housing (20) is pivotably arranged at the frame (10) by means of a first pivot means (28), for pivoting the cutter housing (20) between the normal position of use and a cleaning position. In the cleaning position, the normal (n) of the first opening (26a) of the granule chamber (22) points towards a surface plane of the substrate.

A machine for distributing loosefill insulation material is provided. The machine includes a chute having an inlet end and an outlet end. The inlet end is configured to receive compressed loosefill insulation material. A lower unit has a shredding chamber configured to receive the compressed loosefill insulation material from the outlet end of the chute. The shredding chamber includes a plurality of shredders configured to shred, pick apart and condition the loosefill insulation material. The shredders include a shredder shaft and a plurality of vane assemblies. The vane assemblies are oriented such that adjacent vane assemblies are offset from each other by an angle in a range of from about 45 to about 75. A discharge mechanism is mounted to receive conditioned loosefill insulation material exiting the shredding chamber. The discharge mechanism is configured to distribute the conditioned loosefill insulation material into an airstream. A blower is configured to provide the airstream flowing through the discharge mechanism.

A machine for distributing loosefill insulation material. The machine includes a chute having an inlet end and an outlet end. The inlet end is configured to receive loosefill insulation material. The chute has a first portion in fluid communication with a second portion and forms an angle with the second portion. A shredding chamber includes a plurality of shredders configured to shred, pick apart and condition the loosefill insulation material. A discharge mechanism is mounted to receive the loosefill insulation material exiting the shredding chamber. The discharge mechanism is configured to distribute the loosefill insulation material into an airstream. A blower is configured to provide the airstream flowing through the discharge mechanism. The angle between the first portion of the chute and the second portion of the chute is configured to control the descent of the loosefill insulation material into the shredding chamber.

A bone grinder may have a grinding chamber, an intermediate zone, and a primary cutting element and a secondary cutting element. The intermediate zone may have a first wall and a second wall within the grinding chamber, and the intermediate zone may separate the primary cutting element from the secondary cutting element. The first wall and the second wall may slope inward such that a distance between the first wall and the second wall generally decreases from the primary cutting element to the secondary cutting element. The primary cutting element and the secondary cutting element may be positioned within the grinding chamber to sequentially perform primary cutting operations and secondary cutting operations on a bone. A drive mechanism may operatively engage the primary cutting element and the secondary cutting element.