An imaging system registers image data (D.sub.img) in connection with an installation performing at least one action relating to an animal. A system for image data quality assurance contains a control unit and a digital storage unit. The control unit obtains image data (D.sub.img) registered by the imaging system when the installation is in an idle mode. The control unit analyzes the obtained image data (D.sub.img) to determine if a cleaning action to remove dirt (D) from a front window of the imaging system has been performed. If it is determined that such a cleaning action has been performed, control unit (120) causes a point in time for the cleaning action to be recorded in the digital storage unit (130) for use performance tracking of the installation in conjunction with the cleaning actions.

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 for automated milking of milking animals, comprising a cylinder supporting movement of at least one movable component. The cylinder has a wall with a ventilation opening and a cylinder rod which can move in and out of the cylinder. The cylinder wall surrounds at least one variable volume part for movement of the cylinder rod. The opening configures the cylinder to remain in virtual pressure equilibrium with an environment. A gas capture device is connected which has a variable volume and which together with the variable volume part, forms an air-tight gas volume. Thus the variable volume part is kept at almost ambient pressure, so that no unnecessary counter-pressure occurs in the cylinder, during extension and retraction of the cylinder rod. Also less to no exchange of gas and dirt with the environment can take place for longer life and better reliability of the cylinder.

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 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.

Tools in an automatic milking arrangement are picked up by using a robotic arm (110). The robotic arm (110) moves a camera (130) to an origin location (PC) from which the camera (130) registers three-dimensional image data (Dimg3D) of at least one tool (141, 142, 143, 144). The three-dimensional image data is processed using an image-based object identification algorithm to identify objects in the form of the tools and hoses (152). In response to identifying at least one tool, a respective tool position (PT1, PT3, PT4) is determined for each identified tool based on the origin location (PC) and the three-dimensional image data. Then, a grip device (115) is exclusively controlled to the one or more of the respective tool positions (PT1, PT3, PT4) to perform a pick-up operation. Thus, futile attempts to pick-up non-existing or blocked tools can be avoided.

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 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.

A method for milking a dairy animal with a robot milking device including a teat position determination system and a controller. The method includes allowing the robot milking device, with the help of the teat position determination system, to make one or more connection attempts for connecting at least one milking cup to a teat of the dairy animal, and milking with all connected milking cups where the controller records a number of failed connection attempts. The number of failed connection attempts #MA in a predefined number of milkings, which number of milkings is at least equal to a predefined number #MB, fulfils a predefined criterion, automatically adapting the milking criterion by means of the controller.

The present invention discloses, inter alia, a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); a plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The invention also discloses a method of positioning at least one of a plurality of mobile units in an FDR comprising steps of providing a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); and the plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The present invention further discloses a dairy farm characterized by (a) an array of n stalls side-by-side along an X axis on the dairy animal's level. Each of the stalls is configured by means of size and shape to accommodate a dairy animal, having a main axis Y that is substantially perpendicular to axis X, a front side and an opposite rear side; and (b) a common elevated road surface provided on a higher level, above the stalls. This upper road surface extends along the X axis and is constructed to allow free passage of mobile units, including mobile longitudinal milking units, in a direction along the X axis, along the Y axis, a rotation about the X axis, a rotation about the Y axis, a rotation about the Z axis, and any combination thereof. The present invention further discloses means and method that in a stall, a gate located between the animal and the feeding line is thereby configured to at least temporarily prevent or otherwise limit free access of said animal to its feed.