In one embodiment, a minimally-processed microwaveable lobster product including a lobster tail, a fat-containing composition, and a microwaveable package. The lobster tail has a shell containing lobster meat. The shell has a longitudinal axis with at least one cut formed generally parallel to the longitudinal axis. The fat-containing composition is disposed in a region above the lobster tail. The microwaveable package has first and second resilient layers. The first resilient layer is disposed under the lobster tail and contacts the lobster tail. The second resilient layer is disposed above the lobster tail and contacts the lobster tail and the fat-containing composition.

A shrimp processing machine includes a frame assembly, a drive assembly coupled therewith, a bracket member, and an adjustable cutting assembly. The adjustable cutting assembly is movable between a raised position and a lowered position and includes a cutting device and an adjustable cam plate operably coupled with the cutting device. The adjustable cam plate has a cam body, an adjustment mechanism, and an engagement region having first, second, and third engagement surfaces. The adjustable cutting assembly is adjustable between a first configuration whereby the cutting device has a slow drop-in rate and a second configuration whereby the cutting device has a fast drop-in rate.

In one embodiment, a minimally-processed microwaveable lobster product including a lobster tail, a fat-containing composition, and a microwaveable package. The lobster tail has a shell containing lobster meat. The shell has a longitudinal axis with at least one cut formed generally parallel to the longitudinal axis. The fat-containing composition is disposed in a region above the lobster tail. The microwaveable package has first and second resilient layers. The first resilient layer is disposed under the lobster tail and contacts the lobster tail. The second resilient layer is disposed above the lobster tail and contacts the lobster tail and the fat-containing composition.

A system and method for preparing a shelled crustacean body part for meat extraction are provided. The method involves capturing an image of said body part, evaluating the thickness of the shell from the image, determining from the thickness evaluation at least one laser parameter for forming a line of weakness within the shell, the line of weakness being dimensioned to facilitate meat extraction, while preserving the sensory characteristics of the meat, and sweeping a laser beam on the body part in accordance with the laser parameter to form the line of weakness within the shell. The method and system provide the advantage of facilitating meat extraction without compromising the quality or commercial value of the meat all while increasing productivity and performance in comparison with completely manual extraction techniques.

An automated method for crab meat picking which has an image processing system configured with an imaging sub-system and an image processing sub-system acting in cooperation with each other where the image processing system operates in accordance with a processing routine. An image of a crab to be processed is obtained by the imaging sub-system which is transmitted to the image processing system where the processing routine determines appropriate cut lines to be made on the crab being processed based on instructions from the image processing sub-system. The crab being processed is then cut in accordance with the appropriate cutting lines developed.

The invention provides a sensor-guided, automated system that is capable of intelligently cutting crustaceans, such as crab and lobster, into a plurality of portions, as directed. More particularly, the present system is capable of effectively butchering each individual crustacean in response to how the system's sensor(s) assess the physical characteristics of each crustacean as it arrives via a conveyor belt. The system generally comprises: an intake apparatus for receiving a crustacean; a sensor-guided positioning (SGP) system for determining the presence, location, orientation and size of the crustacean on the intake apparatus, coupling the crustacean, and placing the crustacean into a holding system for butchering; a holding system for retaining the crustacean in an optimal fixed position for butchering; a sensor-guided butchering (SGB) system for determining the locations on a crustacean body to be cut based on the desired output of crustacean portions, and cutting the crustacean at the chosen locations to produce optimal crustacean products; and an outlet apparatus which discharges the butchered crustacean from the system for subsequent packaging.

A novel method for automated extraction of crawfish tail meat comprises placing cooked crawfish on a tray having a bottom slot, applying a downward pressure to the cooked crawfish, extending a rotating brush through the bottom slot to urge the cooked crawfish into a horizontally exposed position, extending a rotating blade through the bottom slot to an incision, then applying a vacuum force to the bottom slot simultaneous to an increase in the downward pressure, causing the cooked crawfish to bulge and the tail meat to be extracted through the slot, after which the carcass is ejected. A plurality of trays can either be rotated in a circular path or conveyed along a linear path above the various tools as cooked crawfish are loaded and carcasses are ejected.

An apparatus for removing meat from crustacean legs includes a conveyor, and a plurality of leg meat extraction rollers. The conveyor has a plurality of leg slots arranged in a machine direction, each leg slot extending laterally in a cross-machine direction. The leg meat extraction rollers are positioned adjacent the conveyor laterally outwardly of the leg slots and oriented to receive crustacean legs moved laterally outwardly from the leg slots.

The invention provides a sensor-guided, automated system that is capable of intelligently cutting crustaceans, such as crab and lobster, into a plurality of portions, as directed. More particularly, the present system is capable of effectively butchering each individual crustacean in response to how the system's sensor(s) assess the physical characteristics of each crustacean as it arrives via a conveyor belt. The system generally comprises: an intake apparatus for receiving a crustacean; a sensor-guided positioning (SGP) system for determining the presence, location, orientation and size of the crustacean on the intake apparatus, coupling the crustacean, and placing the crustacean into a holding system for butchering; a holding system for retaining the crustacean in an optimal fixed position for butchering; a sensor-guided butchering (SGB) system for determining the locations on a crustacean body to be cut based on the desired output of crustacean portions, and cutting the crustacean at the chosen locations to produce optimal crustacean products; and an outlet apparatus which discharges the butchered crustacean from the system for subsequent packaging.

An apparatus for processing a crustacean body part is disclosed. The apparatus includes a conveyor, a first blade, and a first fluidic device. The conveyor has a downstream direction and a first region for supporting a crustacean body part. The first fluidic device is drivingly coupled to the first blade, and actuation of the first fluidic device moves the first blade into the first region. Methods of processing a crustacean body part, methods and apparatus for cracking a crustacean shell, controllers for directing processing of a crustacean body part, and pre-cut seafood items are also disclosed.