A method for milking a dairy animal by means of a robotic milking device containing milking cups, a teat position-determining device, a robot arm in a rest position that carries all milking cups and attaches these to the teats, and a control unit. The dairy animal is milked at an intended milking frequency. The method involves determining if the distance between two teats of the dairy animal is greater than a first threshold distance by means of the teat position-determining device. If the distance is at most equal to the first threshold distance, a usual attachment and milking step is performed. If the distance is greater than the first threshold distance, a modified milking step is performed. A corresponding device is also provided. Milking of the second teat only takes place when the udder has already shrunk, and the teats are closer together as a result.

A milking robot for the fully automatic milking of dairy animals includes at least one moving component and a cylinder configured to support a movement of the component. The cylinder has a cylinder wall having an aeration opening, as well as a cylinder rod slidable into and out of the cylinder. The cylinder wall surrounds at least one variable volume part, which volume part is free from pressure fluid connections for displacement of the cylinder rod. The cylinder is configured to remain, via the opening, substantially in pressure equilibrium with an environment of the cylinder. To the cylinder wall around the aeration opening is connected a gas collecting device which has a changeable volume and which, together with the variable volume part, forms an airtight gas volume. In addition, the gas collecting device has a minimum volume greater than zero.

A device suitable for attachment to a milking platform at a milking position has a strippings viewing area and a light source, which is operable to illuminate in a suitable manner the strippings viewing area to enhance the visibility to an operator of any mastitis symptoms in use and/or to illuminate the udder to facilitate inspection or treatment. The light source may also be operable to give continuous or intermittent colour signals to the operator and the device might also include an alpha-numeric area. The device might form part of a leg separator and/or sprayer and/or milk hose support. A milking platform with such a device is also claimed.

A milking robot system for milking of a dairy animal with teats includes milking cups, a robot arm for attaching the milking cups to the teats, a teat detector configured to detect the position of the teats, and a compressed air system for providing dry compressed air to at least part of the milking robot system. The teat detector comprises a housing containing an optical sensor. The compressed air system is operatively connectable with the inside of the housing via an air line in order to at least partly replace air which is present in the housing by an amount of dry air from the compressed air system. This replacement operation may be performed directly, under pressure, or by first extracting air by means of an additional system and then replenishing it with dry air from the compressed air system.

An automatic milking installation controlled by a system including: a graphical user interface enabling user interaction with the automatic milking installation via at least one display view, an imaging unit recording image data representing at least one portion of a dairy animal, the imaging unit having a transparent cover surface configured to protect an optics section of the imaging unit and through which transparent cover surface the image data are recorded, and a control unit receiving the recorded image data, and based thereon, producing a control signal for controlling functions of the automatic milking installation. The control unit further processes the recorded image data to determine a parameter indicating an amount of dirt on the transparent cover surface, and generates graphics data for presentation to the user via the graphical user interface, which includes at least one graphical element reflecting the amount of dirt on the transparent cover surface.

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.

An implement for automatically milking a dairy animal, such as a cow, comprises a milking parlour, a sensor for observing a teat, and a milking robot for automatically attaching a teat cup to the teat. The milking robot comprises a robot control that is connected to the sensor. The sensor comprises a radiation source for emitting light, a receiver for receiving electromagnetic radiation reflected from the dairy animal, a lens, and sensor control unit. The sensor comprises a matrix with a plurality of rows and a plurality of columns of receivers. The sensor control unit is designed to determine for each of the receivers a phase difference between the emitted and the reflected electromagnetic radiation in order to calculate the distance from the sensor to a plurality of points on the part to be observed of the dairy animal.

A control unit that controls an automatic milking machine to operate in accordance with control commands and/or parameter settings received from either of a local user interface fixedly arranged at the milking machine or a remote terminal, where the control unit, in response to receiving a lock command from one of the local user interface or the remote terminal, causes the automatic milking machine to operate in a single-control mode in which it operates exclusively to commands and/or parameter settings received from the one of the local user interface or the remote terminal that generated the lock command, in order to ensure predictable and safer operation of the milking machine particularly in view of personnel located in proximity of the milking machine.

An implement for automatically milking a dairy animal, such as a cow, comprises a milking parlour, a sensor for observing a teat, and a milking robot for automatically attaching a teat cup to the teat. The milking robot comprises a robot control that is connected to the sensor. The sensor comprises a radiation source for emitting light, a receiver for receiving electromagnetic radiation reflected from the dairy animal, a lens, and sensor control unit. The sensor comprises a matrix with a plurality of rows and a plurality of columns of receivers. The sensor control unit is designed to determine for each of the receivers a phase difference between the emitted and the reflected electromagnetic radiation in order to calculate the distance from the sensor to a plurality of points on the part to be observed of the dairy animal.

An apparatus includes a platform, controller, and first and second extension members, brush tool members, and brush tools. The platform has a length orthogonal to and greater than its width. The first and second extension members are movably coupled to the platform and their longitudinal axes are parallel to the length of the platform. The first and second brush tool members are coupled to and extend along the longitudinal axes of the first and second extension members respectively. The first and second brush tools are coupled to and extend along the longitudinal axes of the first and second brush tool members respectively. The controller moves the first extension member towards the front end of the platform, retracts the first extension member towards the back end of the platform, and at a second time after the first time, moves the second extension member towards the front end of the platform.