A fish processing device and method of use, the device including: a channel; a sensor located within or adjacent to the channel; a barrier, the barrier to assist in preventing a fish passing through the channel; and a control system, wherein the control system controls the barrier in response to an output of the sensor. The method including the steps of: detecting that a fish is incorrectly orientated in a channel; and controlling a barrier to assist in preventing the fish from passing through the channel.

A fish feed-in device (1) for feeding fish (9) to a fish processing device (7) comprises a delivery conveying means (3) which is equipped with a controllable positioning drive (35) and a controllable conveying drive (36). The delivery conveying means (3) can be moved by the controllable positioning drive (35) into a first state (301) released by the fish (9) in a deposit space (11), into a second state (302) for grasping, centred holding and conveying of the fish (9) accessing said fish in the deposit space (11) and, in cooperation with the controllable conveying drive (36), into a third state (303) which releases the fish (9) after conveying at a fish delivery point (42) which is defined by a controlled delivery time with associated controlled fish delivery speed.

A fish feed-in device (1) for feeding fish (9) to a fish processing device (7) comprises a delivery conveying means (3) which is equipped with a controllable positioning drive (35) and a controllable conveying drive (36). The delivery conveying means (3) can be moved by the controllable positioning drive (35) into a first state (301) released by the fish (9) in a deposit space (11), into a second state (302) for grasping, centred holding and conveying of the fish (9) accessing said fish in the deposit space (11) and, in cooperation with the controllable conveying drive (36), into a third state (303) which releases the fish (9) after conveying at a fish delivery point (42) which is defined by a controlled delivery time with associated controlled fish delivery speed.

Methods and systems for processing fish, such as salmon, are provided which enable filleting of the fish in a particular efficient manner. An example method includes exposing a backbone of a fish from a belly side of the fish, positioning the backbone of the fish on a conveyor device, and conveying the fish with the backbone in contact with the conveyor device. The conveyor may be a spiked chain, and positioning the backbone of the fish on the conveyor device may include engaging the backbone of the fish with the spiked chain such that the fish straddles the spiked chain as the fish is transported. The method may further include cutting the fish from the dorsal side on each of opposing sides of a central plane of the fish to a location adjacent a connection of the pinbones of the fish with the vertebrae of the fish while the fish is conveyed with the backbone in contact with the conveyor device, and subsequently peeling the ribs and ventral spines from fillets of the fish.

Methods and systems for processing fish, such as salmon, are provided which enable filleting of the fish in a particular efficient manner. An example method includes exposing a backbone of a fish from a belly side of the fish, positioning the backbone of the fish on a conveyor device, and conveying the fish with the backbone in contact with the conveyor device. The conveyor may be a spiked chain, and positioning the backbone of the fish on the conveyor device may include engaging the backbone of the fish with the spiked chain such that the fish straddles the spiked chain as the fish is transported. The method may further include cutting the fish from the dorsal side on each of opposing sides of a central plane of the fish to a location adjacent a connection of the pinbones of the fish with the vertebrae of the fish while the fish is conveyed with the backbone in contact with the conveyor device, and subsequently peeling the ribs and ventral spines from fillets of the fish.

A fish supply system automatedly conveys fish with defined head/tail and prone/supine alignment to a fish processing apparatus. A speed conveyor transverse axially conveys fish with defined alignments to the apparatus. Feeding apparatuses are arranged above the speed conveyor, each having a cascade conveyor for transverse axially conveying fish, having receptacles separated from by controllable flaps. A clocking flap controls output to the speed conveyor from the last receptacle. A supply device includes a first central conveyor belt, flow scales determining fish regulated mass throughput onto the belt. A speed regulatable second central conveyor belt follows the first conveyor belt. Conveyor strands continuously connect the second belt with the feeding, wherein control flaps separate fish from the second conveyor belt to the conveyor strands. A control device connects with and technically controls the first and second conveyor belts, flow scales, the flaps, conveyor strands, speed conveyor and feeding apparatuses.

A fish supply system automatedly conveys fish with defined head/tail and prone/supine alignment to a fish processing apparatus. A speed conveyor transverse axially conveys fish with defined alignments to the apparatus. Feeding apparatuses are arranged above the speed conveyor, each having a cascade conveyor for transverse axially conveying fish, having receptacles separated from by controllable flaps. A clocking flap controls output to the speed conveyor from the last receptacle. A supply device includes a first central conveyor belt, flow scales determining fish regulated mass throughput onto the belt. A speed regulatable second central conveyor belt follows the first conveyor belt. Conveyor strands continuously connect the second belt with the feeding, wherein control flaps separate fish from the second conveyor belt to the conveyor strands. A control device connects with and technically controls the first and second conveyor belts, flow scales, the flaps, conveyor strands, speed conveyor and feeding apparatuses.

A fish handling unit for processing live fish is provided. Such fish handling unit includes an inspection system configured to inspect a plurality of live fish. A conveyor assembly transports the live fish to the inspection system. At least one robotic cell is in communication with the inspection system. The robotic cell has a controller configured to control operation thereof. An end effector is operably engaged with the robotic cell. The end effector interacts with the live fish moving along the conveyor assembly, based on information determined by the inspection system and received by the controller. The end effector may optionally be an integrated gripper and injection assembly capable of orientation and injection of the live fish. Associated devices and methods are also provided.

A conveyor line and carrier including a hook or hooks for suspending poultry or poultry parts by the legs. A carriage for moving the carrier with the suspended poultry or poultry parts along a track of the conveyor line. Arranged with at least a first rotatable vertical rod suspended from the carriage, which first rotatable rod is provided with a sideways extending arm for adjusting an orientation of the poultry or poultry parts with reference to the carriage.

Methods and systems for processing fish are provided which enable the efficient conveyance of fish products from one fish processing subsystem or station to another in a particularly reliable and robust form factor. The systems may include a first fish processing subsystem configured to process fish with the fish orientated in a first orientation; a second fish processing subsystem configured to process the fish with the fish orientated in a second orientation different from the first orientation; and a conveyor system that couples the first fish processing subsystem to the second fish processing subsystem with the conveyor system being configured to receive the fish in the first orientation and deliver the fish in the second orientation. Related methods of conveying and processing fish are also provided.