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 apparatus is described that includes a longitudinally extending liner made from a resiliently deformable material. The liner is mounted on a rigid support shell. The liner comprises an outer hood configured to lie over an outer surface of the rigid support shell, and an inner barrel configured to be disposed within the rigid support shell and to define an internal volume. The inner barrel extends in the longitudinal direction away from an opening at a first end of the liner, through which opening an animal teat is insertable into the internal volume. The inner barrel is connected to the outer hood at a plurality of longitudinally extending connection regions on an inner surface of the outer hood. These connections define boundary conditions that limit the deformation of the barrel that encloses the teat can be set by the configuration of the liner itself.

A milking apparatus is described that includes a longitudinally extending liner made from a resiliently deformable material. The liner is mounted on a rigid support shell. The liner comprises an outer hood configured to lie over an outer surface of the rigid support shell, and an inner barrel configured to be disposed within the rigid support shell and to define an internal volume. The inner barrel extends in the longitudinal direction away from an opening at a first end of the liner, through which opening an animal teat is insertable into the internal volume. The inner barrel is connected to the outer hood at a plurality of longitudinally extending connection regions on an inner surface of the outer hood. These connections define boundary conditions that limit the deformation of the barrel that encloses the teat can be set by the configuration of the liner itself.

A system and method for verifying proper milking system performance during the milking process. The system and method incorporates an integral function within a pulsator valve device that routinely performs functional evaluations and is capable of reporting results to the user. An additional air valve apparatus can be used to supply additional air to the pulsator valve device.

In a headlock system having a plurality of n headlock cells, each of the n cells being adapted to enclose at least one animal; n is an integer greater than 1; a system for locating the position of at least one animal, the system comprising: at least one identification means adapted to transmit at least one identification signal associated with said at least one animal; at least one locating means adapted to generate at least one location signal associated with said at least one animal; and, a data processing system in communication with said at least one identification means and said at least one locating means, adapted to analyze said signals, said analyzed signals comprising the position within a predetermined region in said headlock system of each of said at least one animals as a function of time.

In a headlock system having a plurality of n headlock cells, each of the n cells being adapted to enclose at least one animal; n is an integer greater than 1; a system for locating the position of at least one animal, the system comprising: at least one identification means adapted to transmit at least one identification signal associated with said at least one animal; at least one locating means adapted to generate at least one location signal associated with said at least one animal; and, a data processing system in communication with said at least one identification means and said at least one locating means, adapted to analyze said signals, said analyzed signals comprising the position within a predetermined region in said headlock system of each of said at least one animals as a function of time.

A bulk fluid monitoring system and method for monitoring milk is provided, including a plurality of sensors for providing information in relation to properties of a bulk fluid, a memory for holding data parameters including information provided by the sensors and a predetermined time-and-temperature curve for a fluid, a processor for determining whether the information in relation to properties of the bulk fluid is within the bounds of the time and temperature curve for a fluid.

Disclosed is a monitoring milk meter, which is able to monitor the livestock being milked, as well as general procedures performed in the milking farm, such as the CIP procedure.

A milking apparatus is described that includes a longitudinally extending liner made from a resiliently deformable material. The liner is mounted on a rigid support shell. The liner comprises an outer hood configured to lie over an outer surface of the rigid support shell, and an inner barrel configured to be disposed within the rigid support shell and to define an internal volume. The inner barrel extends in the longitudinal direction away from an opening at a first end of the liner, through which opening an animal teat is insertable into the internal volume. The inner barrel is connected to the outer hood at a plurality of longitudinally extending connection regions on an inner surface of the outer hood. These connections define boundary conditions that limit the deformation of the barrel that encloses the teat can be set by the configuration of the liner itself.

A milking apparatus is described that includes a longitudinally extending liner made from a resiliently deformable material. The liner is mounted on a rigid support shell. The liner comprises an outer hood configured to lie over an outer surface of the rigid support shell, and an inner barrel configured to be disposed within the rigid support shell and to define an internal volume. The inner barrel extends in the longitudinal direction away from an opening at a first end of the liner, through which opening an animal teat is insertable into the internal volume. The inner barrel is connected to the outer hood at a plurality of longitudinally extending connection regions on an inner surface of the outer hood. These connections define boundary conditions that limit the deformation of the barrel that encloses the teat can be set by the configuration of the liner itself.