A fish head cutting machine for decapitating a fish, comprising: a) a fish support for supporting a fish in an infeed loading zone with its belly side down and its backbone in a substantially horizontal orientation; b) a guide mechanism positioned adjacent the fish support to hold the fish via an anatomical body part, such as its gill plate, collar bone, pectoral fin or pelvic fin, so that only the body of the fish is supported by the fish support; c) a drive mechanism transporting the fish in a downward direction and at an acute angle to vertical from the infeed loading zone downstream to a head cutting zone while the fish is supported on the fish support and held by the guide mechanism; d) a head pusher located between the infeed loading zone and the head cutting zone that engages the head of the fish and tips the head of the fish upwardly and rearwardly as the fish moves downstream to the head cutting zone; and e) head cutting blades located downstream of the head pusher in the cutting zone that cut the head of the fish from the body of the fish.

A vertical packaging machine for packaging products is provided that includes a forming element with an upper mouth and a hopper upstream of the forming element. At least the hopper and the forming element form a conduit through which the product falls. A flow generator includes an injection device for injecting a gaseous fluid through a distributor for directing the fluid to the conduit. The distributer has an inlet mouth for receiving the gaseous fluid and an outlet mouth with an area smaller than the area of the inlet mouth. The injection device is controlled by a control device that is configured to cause the injection device to perform an injection for each product to be packaged in one and the same package, the start and end of which depend on the position of the product with respect to the upper mouth and the outlet mouth.

Gutting machine for fish, comprising a conveyor belt to receive fish, where the fish is placed with the abdomen facing a number of cutting and cleaning tools for gutting and cleaning of the fish when it is transported on said conveyor belt, in which said conveyor belt is equipped with a number of holding devices where respective holding devices are adapted for firmly holding the fish, and that one or more barriers arranged adjoining said conveyor belt are adapted to slow down the movement of the fish until the fish is firmly held in a respective holding device and is brought by the conveyor belt in its direction of movement. Also described is a method for gutting the fish in a gutting machine.

The invention provides a gutting device for gutting a fish along its abdominal cavity. A blade for cutting the fish open, and a shielding element are movably mounted on a controllable movable arm. The shielding element has a blunt tip, and it is arranged for being in: 1) a retracted position, where the shielding element allows the blade to cut the fish, 2) a tracking position, where the blunt tip of the shielding elements is inside the abdominal cavity of the fish, so as to track the end of the abdominal cavity of the fish, and 3) a shielding position, where the shielding element is pushed upwards by contact with the end of the abdominal cavity at a genital opening of the fish, thereby shielding the blade from further contact with the fish. This provides a precise method for without unintentionally damaging the fish.

A revolutionized tuna process according to this invention generally comprising the steps of thawing of frozen tuna, de-heading and degutting, fileting, de-skinning, cleaning of the de-skinned tuna filet, pre-cooking, cooling, packing of the cleaned and pre-cooked tuna loin, and sterilizing the packed tuna loin or freezing the tuna loin. Not only does the process according to this invention reduces the energy utilization by half, it also significantly reduces the time required for cooking and cooling. Therefore, the whole processing time is significantly reduced from at least 8.0 hours in the conventional process to less than 30 minutes.

A method and apparatus for filleting fish to produce high yielding fillets from relatively short bodied fish in the size range of about 600 grams to about 3.5 kilograms dependent on species. The method and apparatus are designed to be capable of handling salmon, tilapia, trout, arctic char, barramundi, snappers, walleye pike, striped bass and similar species where the rib follows the contour of the belly cavity. Further, the method and apparatus incorporate belly opening and eviscerating components prior to subjecting the fish to a backbone removal system so that the fish need only be headed, but not gutted, before introduction into the machine.

The invention provides a gutting device for gutting a fish along its abdominal cavity. A blade for cutting the fish open, and a shielding element are movably mounted on a controllable movable arm. The shielding element has a blunt tip, and it is arranged for being in: 1) a retracted position, where the shielding element allows the blade to cut the fish, 2) a tracking position, where the blunt tip of the shielding elements is inside the abdominal cavity of the fish, so as to track the end of the abdominal cavity of the fish, and 3) a shielding position, where the shielding element is pushed upwards by contact with the end of the abdominal cavity at a genital opening of the fish, thereby shielding the blade from further contact with the fish. This provides a precise method for without unintentionally damaging the fish.

A method for ecological utilization of silver carp, including the pretreatment of silver carp and the process of making canned fish surimi. The fish meat of silver carp is processed canned surimi. The fish heads and bones are heated and undergo enzymatic hydrolysis by enzymes, and the residues of the filtration are prepared for fish bone powder. A filtration membrane is used to reduce the volume of the filtrate to 50% of fish surimi and then the filtrate is frozen to ice. The frozen part can be added to fish surimi. The transparent part from membrane filtration was used to produce protein powder or ingredients for beverages. Fish offal can be used to produce protein liquid fertilizer. Fish scales and skins can be used to produce collagen. The method adopts ecological utilization, which makes the silver carp meat used effectively, including its processed wastes. The method is a closed cycle process such that that no pollutants or wastes are discharged during the process.

Gutting machine for fish, comprising a conveyor belt to receive fish, where the fish is placed with the abdomen facing a number of cutting and cleaning tools for gutting and cleaning of the fish when it is transported on said conveyor belt, in which said conveyor belt is equipped with a number of holding devices where respective holding devices are adapted for firmly holding the fish, and that one or more barriers arranged adjoining said conveyor belt are adapted to slow down the movement of the fish until the fish is firmly held in a respective holding device and is brought by the conveyor belt in its direction of movement. Also described is a method for gutting the fish in a gutting machine.

A method and apparatus for filleting fish to produce high yielding fillets from relatively short bodied fish in the size range of about 600 grams to about 3.5 kilograms dependent on species. The method and apparatus are designed to be capable of handling salmon, tilapia, trout, arctic char, barramundi, snappers, walleye pike, striped bass and similar species where the rib follows the contour of the belly cavity. Further, the method and apparatus incorporate belly opening and eviscerating components prior to subjecting the fish to a backbone removal system so that the fish need only be headed, but not gutted, before introduction into the machine.