The present disclosure involves a calculation method and device for intelligent cutting squid white slices, the calculation method being implemented on the device for intelligent cutting squid white slices. The calculation method may be implemented on a calculation device, the calculation device may have at least one processor and at least one storage medium including an instruction set used for intelligent cutting the squid white slices, the calculation method including: reading a laser point cloud data of a three-dimensional (3D) topography of the squid white slices; optimizing the laser point cloud data; extracting an effective area of the squid white slices; determining a cutting zero point; determining a cutting process area; and determining optimization of a cutting point position and a cutting angle. The one or more embodiments provided by the present disclosure may satisfy the needs of large-scale continuous production in factories, reduce labor costs, and improve production efficiency.

A seafood sheller for cracking or cutting open shells of, for example, crustaceans is described herein. The seafood sheller having a handle member, an upper beak member and a lower bladed member. The upper beak member extending longitudinally forward from the handle member and having a distal end opposite from the handle member and an upper beak member bottom that extends longitudinally from the handle member. The lower blade member having a blade edge and a blade base, the blade edge extending longitudinally forward beneath the upper beak member bottom from the blade base. The blade base being connected to the upper beak member at a rearward portion of the upper beak member bottom. The lower blade member further having a distal end opposite from the blade base, the distal end of the upper beak member longitudinally extending forwardly beyond the distal end of the lower blade member.

A separation and singulation system for presenting shrimps or other product individually to a processor. The separation and singulation system includes a divider pan that separates a layer of shrimp into several lanes, a shaker pan that receives the lanes of shrimp and agitates them to separate clumps of shrimp and a flume for providing further singulation and acceleration of the shrimp. The singulated, separated shrimps are then sent to a processor.

An oyster clamp comprising a base element having an indentation for receiving an oyster to be opened. A lip coupled to the base element hangs over and impinges upon an edge of a work surface on which the oyster clamp is placed, and a slide inhibitor is arranged to prevent the base element from sliding on the work surface. A backstop is affixed to the base element to prevent the oyster from exiting the back of the oyster clamp when in use. An oyster clamping element is operatively coupled to a handle and to the base element, such that operating the handle causes the clamping element to push the oyster down against the base element.

The present disclosure involves a calculation method and device for intelligent cutting squid white slices, the calculation method being implemented on the device for intelligent cutting squid white slices. The calculation method may be implemented on a calculation device, the calculation device may have at least one processor and at least one storage medium including an instruction set used for intelligent cutting the squid white slices, the calculation method including: reading a laser point cloud data of a three-dimensional (3D) topography of the squid white slices; optimizing the laser point cloud data; extracting an effective area of the squid white slices; determining a cutting zero point; determining a cutting process area; and determining optimization of a cutting point position and a cutting angle. The one or more embodiments provided by the present disclosure may satisfy the needs of large-scale continuous production in factories, reduce labor costs, and improve production efficiency.

The present disclosure involves a calculation method and device for intelligent cutting squid white slices, the calculation method being implemented on the device for intelligent cutting squid white slices. The calculation method may be implemented on a calculation device, the calculation device may have at least one processor and at least one storage medium including an instruction set used for intelligent cutting the squid white slices, the calculation method including: reading a laser point cloud data of a three-dimensional (3D) topography of the squid white slices; optimizing the laser point cloud data; extracting an effective area of the squid white slices; determining a cutting zero point; determining a cutting process area; and determining optimization of a cutting point position and a cutting angle. The one or more embodiments provided by the present disclosure may satisfy the needs of large-scale continuous production in factories, reduce labor costs, and improve production efficiency.

A system for processing shellfish includes an input hopper that receives a batch of shellfish to be processed. A conveyer is positioned to receive shellfish from the input hopper and transports the shellfish through the system. The conveyor defines a plurality of holes that allow cleaning substances to pass through the conveyor. A washing system comprising a least one nozzle that dispenses cleaning substances to the shellfish being transported by the conveyor. An operator station includes at least one container for depositing market-ready shellfish passing along the conveyor. At least one optical sensor is positioned to detect the market-ready shellfish being placed into the at least one container. A counter is electrically connected to the optical sensor and records a number of shellfish being placed in the at least one container. An output hopper is positioned proximate to an end of the conveyor to catch rejected shellfish.

A system for processing shellfish includes an input hopper that receives a batch of shellfish to be processed. A conveyer is positioned to receive shellfish from the input hopper and transports the shellfish through the system. The conveyor defines a plurality of holes that allow cleaning substances to pass through the conveyor. A washing system comprising a least one nozzle that dispenses cleaning substances to the shellfish being transported by the conveyor. An operator station includes at least one container for depositing market-ready shellfish passing along the conveyor. At least one optical sensor is positioned to detect the market-ready shellfish being placed into the at least one container. A counter is electrically connected to the optical sensor and records a number of shellfish being placed in the at least one container. An output hopper is positioned proximate to an end of the conveyor to catch rejected shellfish.

An apparatus for cleaning crustacea or game has a container, a pipe positioned adjacent to a wall of the container, and a connector fluidically connected to the pipe adjacent a lower end of the pipe and having a portion extending outwardly of the wall of the container. The pipe has a plurality of apertures adapted to direct a flow of water toward a portion of the wall spaced from the pipe such that the flow of water creates a cyclonic path in the container. The pipe extends generally vertically adjacent to the wall of the container. The plurality of apertures are formed in spaced relation to each other along a length of the pipe. A drain is affixed through a wall of the container adjacent to the bottom of the container.

An apparatus for cleaning and cooking seafood or crustacea has a container with an interior volume defined by a tapered wall, a basket removably received in the interior volume of the container, a pipe positioned adjacent to the wall of the container and having a plurality of apertures adapted to direct the flow of water through holes of the basket, and a connector fluidically connected to the pipe and having a portion extending outwardly of the tapered wall of the container. The basket is tapered so as to be nestable within the tapered wall of the container. The basket has an indentation with holes extending over the pipe. A pot is spaced from the container and nestably removably receives the basket therein.