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 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.

A method for cooling milk in a milking arrangement, and a milk cooling apparatus of the milking arrangement that has a coolant circuit for heat exchange between milk and a coolant and a refrigerant circuit for heat exchange between a refrigerant and the coolant, where the method includes controlling the refrigerant circuit to maintain a predefined temperature range, receiving a first signal relating to commencement or increase of a milk flow from a milking system of the milking arrangement, starting or increasing circulation of coolant in the coolant circuit, and leading the milk flow through the milk cooling apparatus.

A method for cooling milk in a milking arrangement, and a milk cooling apparatus of the milking arrangement that has a coolant circuit for heat exchange between milk and a coolant and a refrigerant circuit for heat exchange between a refrigerant and the coolant, where the method includes controlling the refrigerant circuit to maintain a predefined temperature range, receiving a first signal relating to commencement or increase of a milk flow from a milking system of the milking arrangement, starting or increasing circulation of coolant in the coolant circuit, and leading the milk flow through the milk cooling apparatus.

An automatic milking machine extracts milk from the teats of an animal by applying a milking vacuum to a respective teat receiving cavity of a teat cup (111, 112, 113, 114) each in which one of the teats is located during a milking session. The milking session includes a boost phase (TBOOST) and is concluded by an exit phase (TEXIT). During the boost phase (TBOOST), the milking vacuum is applied at an elevated pressure level. During the exit phase, the milking vacuum is applied at one or more levels, each of which is lower than the elevated pressure level. The operation of the automatic milking machine transitions from the boost phase (TBOOST) to the exit phase (TEXIT) when (t2) a temporal criterion is fulfilled.

An automatic milking machine extracts milk from the teats of an animal by applying a milking vacuum to a respective teat receiving cavity of a teat cup (111, 112, 113, 114) each in which one of the teats is located during a milking session. The milking session includes a boost phase (TBOOST) and is concluded by an exit phase (TEXIT). During the boost phase (TBOOST), the milking vacuum is applied at an elevated pressure level. During the exit phase, the milking vacuum is applied at one or more levels, each of which is lower than the elevated pressure level. The operation of the automatic milking machine transitions from the boost phase (TBOOST) to the exit phase (TEXIT) when (t2) a temporal criterion is fulfilled.

A method is proposed for ascertaining the quality and/or the composition of milk, in particular during a milking operation, in which the fill level of the milk in a chamber is determined. After the fill level of the milk in the chamber has been determined, the milk is irradiated using at least one radiation of a predefined wavelength. The intensity of the reflected radiation is measured. The fill level and the intensity of the reflected radiation represent a value pair. Characteristic values are stored in a memory. A characteristic value is assigned to the ascertained value pair. A statement about the quality and/or the composition of the milk can be made from the characteristic value thus ascertained.

A method is proposed for ascertaining the quality and/or the composition of milk, in particular during a milking operation, in which the fill level of the milk in a chamber is determined. After the fill level of the milk in the chamber has been determined, the milk is irradiated using at least one radiation of a predefined wavelength. The intensity of the reflected radiation is measured. The fill level and the intensity of the reflected radiation represent a value pair. Characteristic values are stored in a memory. A characteristic value is assigned to the ascertained value pair. A statement about the quality and/or the composition of the milk can be made from the characteristic value thus ascertained.