An animal feeding vehicle includes a movement control system, a GPS receiver for generating a first set of parameters including location information, a proximity sensor for generating a second set of parameters including spatial information, a position sensor for generating a third set of parameters including motion information, a feeding system including a feeding control system for feeding animals based on a fourth set of parameters. A control unit receives the first, second, third, and fourth sets of parameters, and defines a first mode in which the user controls the movement control system and the feeding control system, and in which the control unit records data representing the first, second, third, and fourth sets of parameters; and a second mode in which the control unit controls the movement control system and the feeding system by comparing recorded data with the first, second, third, and fourth sets of parameters.

In an apparatus for feeding animals including one or more feed dispensing containers from which the animals can take feed which are fed by supply ducts from a supply a device is provided which includes a feed supply duct portion arranged such that the feed falls through the feed supply duct portion under gravity. A drive member is mounted at the duct and includes a plurality of paddle blades of a wheel mounted for rotation about an axis of the wheel such that falling feed in the duct acts to drive the blades to rotate the wheel about the axis and a driven component driven by the wheel. The driven component is in most cases a dispenser for feeding a liquid or particulate additive material from a supply cartridge, which is mounted on a common housing forming the duct and containing the wheel, to an injection opening on the bottom of the housing for addition to the feed passing through the duct portion.

The present invention relates to a dispensing apparatus for the controlled dispensing of a high viscosity feed supplement hydrogel, which has a fluid container (A), a diaphragm pump (1), a fluid box (B) in which dispensing nozzles (6) are arranged. The invention is characterized in that within the fluid box (B) it has a pressure regulator (2), one or more pneumatic dispensing valves (3) associated with the pressure regulator (2), and a fluid distributor (5) connected to the lower outlet openings of each pneumatic dispensing valve (3), wherein to each fluid distributor (5) one or more dispensing nozzle(s) (6) are arranged orderly in several rows, a solenoid valve (4) is connected to an upper outlet connector of the pneumatic dispensing valve (3), an outlet of an air pressure regulator (8) is connected to one of the inlets of the solenoid valve (4) and an outlet of a control box (C) is electronically connected to another inlet of the solenoid valve (4), which control box (C) can also be operated via WIFI by a remote control (9), another outlet of the air pressure regulator (8) is connected to an inlet of the diaphragm pump (1), an optical sensor (7) is arranged in the fluid box (B) for optimal control of the dispensing nozzles (6), an outlet of the optical sensor (7) is connected to one of the inlets of the control box (C).

A system and method for providing a supplement. The system includes a pump having an inlet and an outlet line. The inlet line is coupled to a container, and the container has a supplement. The outlet of the pump is coupled to a nozzle. The system can be housed in a support box which is coupled to a feeder which has feed. Feed is discharged from the feeder, and the pump sprays a supplement to partially coat the discharged feed. Nutrients, vitamins, etc. can be added to the supplement which can add to the value of the feed.

The present invention relates to an automatic feeder and a feeding pipe thereof. A feeding pipe (1) discharges a feed when a pig gnaws a gnawing block (12) thereon, and when the gnawing block (12) is gnawed, a pressure sensor (14) is triggered; a hopper (2) is configured to be filled with a dry feed material; one end of a spiral conveyor (3) is connected with a motor (4), the other end of the spiral conveyor is located in the feeding pipe (1), and the spiral conveyor (3) is configured to convey the dry feed material in the hopper (2) to the feeding pipe (1); the motor (4) provides power for rotation of the spiral conveyor (3); a water supply pipeline (5) provides water for the dry feed material in the feeding pipe (1) for feed mixing; and after receiving a triggering signal of the pressure sensor (14), a control unit (7) controls the motor (4) to be powered on and the water supply pipeline (5) to be opened simultaneously, and when not receiving the triggering signal of the pressure sensor (14), the control unit (7) controls the motor (4) to be powered off and the water supply pipeline (5) to be closed.

An animal shed for accommodating a number of dairy animals includes at least one feeding device for providing feed to the dairy animals; a controller configured to determine the identity of an individual dairy animal at the feeding device and a dose and/or composition of the feed to be provided to the dairy animal by the feeding device; at least one separate watering device for providing drinking water to the dairy animals; and a supply for supplying concentrated feed to the drinking water to be provided to the dairy animals by the watering device. The controller is further configured to determine the identity of an individual dairy animal at the watering device and a dose and/or composition of the concentrated feed to be supplied to the drinking water for the dairy animal.

A method and apparatus for feeding livestock is presented. The method includes feeding livestock using a mobile feed preparation apparatus comprising a processor and a first non-transitory computer readable medium in communication with the processor, wherein the mobile feed preparation apparatus can dispense a plurality of feed rations, each feed ration comprising a base feed and at least one of a plurality of feed additives. The method includes dispensing from the mobile feed preparation apparatus a first feed ration comprising the base feed and a first feed additive, wherein the dispensed first feed ration comprises a dispensed amount of the first feed additive.

Systems and methods for automated pet food dispensing are described. One apparatus includes a receptacle configured to hold a sealed container containing wet pet food. The apparatus may include an electrically-operated plunger configured to interface with the receptacle. A processing system may be connected to the electrically-operated plunger. In one aspect, the processing system is configured to initiate a pet feeding event by actuating the plunger to interface with the receptacle, puncture the sealed container, and dispense the wet pet food into the food bowl. The processing system may maintain a time history to determine one or more future pet feeding events.

Systems and methods for automated pet food dispensing are described. One apparatus includes a receptacle configured to hold a sealed container containing wet pet food. The apparatus may include an electrically-operated plunger configured to interface with the receptacle. A processing system may be connected to the electrically-operated plunger. In one aspect, the processing system is configured to initiate a pet feeding event by actuating the plunger to interface with the receptacle, puncture the sealed container, and dispense the wet pet food into the food bowl. The processing system may maintain a time history to determine one or more future pet feeding events.

A reward dispenser (10) is provided for dispensing an edible reward to a pet. The reward dispenser (10) comprises a reward pouch receiver (42) configured to receive a pouch (44) containing an edible reward for a pet, a dispenser outlet (14) and a peristaltic pump (32) positioned on a reward transfer path between the reward pouch receiver (42) and the dispenser outlet (14). The peristaltic pump (32) is configured to drive an edible reward from a said pouch (44) at the reward pouch receiver (42) to the dispenser outlet (14).