A milking arrangement includes a milking module having at least two milking places, a front gate assembly, a sequence gate assembly, an entrance gate, an independent first drive device for moving the front gate assembly between lower and upper positions, and a second drive device for moving the entrance gate between open and closed positions. An independent third drive device moves the sequence gate assembly from a first position to a second elevated position in which the sequence gates are located at a level above and behind animals standing in respective milking places. The sequence gate assembly being configured to move from the second position to the first position such that the sequence gates urge animals standing in their respective milking places to leave the milking places. A control arrangement controls opening of the entrance gate on basis of the position of the sequence gate assembly.

An automatic milking machine controlled by a control unit that, in response to a control request from a first remote user terminal that indicates an intention to initiate transmission of control commands and/or parameter settings, checks whether at least one control command and/or parameter setting from a second remote user terminal has been received within a particular interval preceding a point in time when the control request was received, and if so, returns status data to the first remote user terminal that indicate an identity of the second remote user terminal so that, based thereon, an operator of the first remote user terminal can decide whether or not to remote control the milking machine at the present point in time.

A method and apparatus (3) for operating a rotary milking platform (1) to maximise the number of animals milked per unit time. The milking platform (1) is rotated about a central vertical axis (4) by a variable speed motor (6), and comprises a plurality of animal accommodating locations (5) for the animals being milked. An entry position (7) and an exit position (9) accommodate animals to and from the platform (1). A position sensor (10) monitors the angular position of the platform (1). An RFID sensor (12) reads the identity of animals entering the platform (1). Historical data relating to milking time per milking session and the milk yield per animal per session is stored in an electronic memory (17). A microprocessor (15) reads signals from flow meters (14) which monitor the milk flow from milking clusters of each animal accommodating location (5). The microprocessor (15) is configured as each animal enters the platform (1) to compute an optimum angular velocity for the platform (1) in order to maximise the number of animals milked per unit time. The optimum angular velocity is computed as a function of the historical data of each animal on the platform (1), and the current milk yield of each animal on the milking platform (1) determined from the flow meter (14).

A milking system for milking a dairy animal includes a milking cup to be attached to a teat of the dairy animal and milking the milk, and an electronic component. The electronic component includes a sensor which is arranged in or on the milking cup for measuring a value of a variable related to the milking, a transmitter for transmitting the measured values, and a power supply for supplying the sensor and/or the transmitter with electrical energy. The power supply may include an inductive power supply with a first coil component and a second coil component, where the first coil component and the electronic component are electrically connected to each other, and where the second coil component is electrically directly connectable to an external source of electrical energy. The milking system also includes a fastening means which holds the first coil component and the second coil component together.

A milking system for milking a dairy animal includes a milking cup to be attached to a teat of the dairy animal and milking the milk, and an electronic component. The electronic component includes a sensor which is arranged in or on the milking cup for measuring a value of a variable related to the milking, a transmitter for transmitting the measured values, and a power supply for supplying the sensor and/or the transmitter with electrical energy. The power supply may include an inductive power supply with a first coil component and a second coil component, where the first coil component and the electronic component are electrically connected to each other, and where the second coil component is electrically directly connectable to an external source of electrical energy. The milking system also includes a fastening means which holds the first coil component and the second coil component together.

The operation of a movable platform (110) in a rotary milking parlor (100) is measured by a movement sensor (210) arranged on the movable platform (110). The movement sensor (210) registers micro movements of the movable platform (110) relative to a fix reference frame via a sensor member measuring displacements in at least one dimension, and/or accelerations in at least one dimension. A wireless sensor signal (SW) reflecting the measurements is emitted by a transmitter to a receiver (230) for processing/analysis, for example to derive a movement signature (S) of the movable platform (110) based on a series of measurement values.

In one aspect the invention is a milking platform (1) for a species of animal to be milked, comprising a deck divided into a series of bales (17), each bale having side and end barriers and being of sufficient size to receive only one animal (5) for milking. Each has a structure (2) (e.g. a box) arranged such that when the platform is in use with the animal to be milked the structure (2) extends upwards from the deck to a height below the animal's abdomen, is between the forelegs of the animal, starts in front of the forelegs and extends towards, but stops before, the hind legs of the animal such that there is sufficient space to fit a set of milking cups to teats of the animal.

A teat sprayer for use in dairy applications is described that uses an articulated arm and system to deliver a spray to a teat and move between multiple dairy animals.

In one aspect the dairy animal teat treatment apparatus, comprises a spray inlet, a spray nozzle, a flow path extending between the spray inlet and the spray nozzle, and an articulated arm conveying the spray nozzle, movement of the articulated arm driven by an actuator. Articulated arm movement may be between a retracted position in which the spray nozzle and articulated arm are retracted and an extended position in which at least part of the articulated arm and spray nozzle thereon is extended, moving the spray nozzle to a position configured to be about an animal's udder.

In a further aspect, the apparatus, comprises an animal sensor positioned generally above and behind an animal bail and directed generally downwards configured to sense the presence of an animal in the animal bail; and a controller configured to actuate spraying of the animal's teats from spray nozzle extension and retraction in response to a signal received from the sensor.

The apparatus may act to reduce cost through reduced numbers of treatment apparatus and/or lower labour costs and expenses; increase accuracy/efficiency through automation and speed of treatment; address issues associated with the inconvenience/space constraints in dairy platform configurations; and minimise the number of sensors required and position these sensors away from the animal bail.

A teat sprayer for use in dairy applications is described that uses an articulated arm and system to deliver a spray to a teat and move between multiple dairy animals.

In one aspect the dairy animal teat treatment apparatus, comprises a spray inlet, a spray nozzle, a flow path extending between the spray inlet and the spray nozzle, and an articulated arm conveying the spray nozzle, movement of the articulated arm driven by an actuator. Articulated arm movement may be between a retracted position in which the spray nozzle and articulated arm are retracted and an extended position in which at least part of the articulated arm and spray nozzle thereon is extended, moving the spray nozzle to a position configured to be about an animal's udder.

In a further aspect, the apparatus, comprises an animal sensor positioned generally above and behind an animal bail and directed generally downwards configured to sense the presence of an animal in the animal bail; and a controller configured to actuate spraying of the animal's teats from spray nozzle extension and retraction in response to a signal received from the sensor.

The apparatus may act to reduce cost through reduced numbers of treatment apparatus and/or lower labour costs and expenses; increase accuracy/efficiency through automation and speed of treatment; address issues associated with the inconvenience/space constraints in dairy platform configurations; and minimise the number of sensors required and position these sensors away from the animal bail.

A system for milking a group of milking animals includes a stationary animal accommodation space having a fixed floor, a plurality of milking stations, and an animal-free space which is closed for the milking animals in the accommodation space and extends adjacent to the milking stations. The system also includes an automatic milking system that includes milking cups and a robot device movable relative to the milking stations, the milking cups being connectable automatically to the teats of a milking animal present in the milking station. The system further includes a milk discharge system having at least one flexible milk line that connects the milking cups to a milk storage tank. The flexible milk line is configured so that the robot device can move from the animal-free space into each of the milking stations while the milk line remains connected to the robot device.