Automatic teat treatment method and apparatus for treatment operations on teats of an animal using a robot apparatus. The method includes initiating automatic detection of spatial teat positions and registering the spatial positions of the detected teats; and deriving a dedicated treating action effective to move the treating device through a dedicated path defined by the registered spatial teat positions and carrying out treatment by moving the treating device through the dedicated path. When not all of the spatial positions are detected, then the method registers the spatial position of each detected teat and derives an adapted treating action effective to move the treating device through an adapted path defined by the registered spatial teat positions and by approximated spatial locations. When no teat spatial positions have been detected, the method derives a default treating action effective to move the treating device through a default treating path.

A system including a 3D camera, memory, and a processor. The processor is configured to obtain the 3D image, identify one or more regions within the 3D image comprising depth values greater than a depth value threshold, and apply the thigh gap detection rule set to identify a thigh gap region. The processor is further configured to demarcate an access region within the thigh gap region, demarcate a teat detection region, partition the 3D image within the teat detection region to generate a plurality of image depth planes, and examine each of the plurality of image depth planes. The processor is further configured to identify one or more teat candidates within the image depth plane, apply the teat detection rule set to the one or more teat candidates to identify one or more teats, and determine position information for the one or more teats.

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.

A method for performing teat related operations in a rotary milking system during an operation condition when a capacity required for performing the operations with respect to the teats of the milking animals is higher than a robot's capacity, includes estimating a required capacity for performing the operations; planning a semi-automated teat related operation procedure based on the robot's capacity and the estimated required capacity, according to which procedure a first fraction of the operations with respect to the teats of the milking animals should be performed automatically by the robot in a first zone, and a second fraction of the operations with respect to the teats of the milking animals should be performed manually in a second zone adjacent to the first zone; and performing the operations with respect to the teats of the milking animals according to the planned semi-automated teat related operation procedure.

A hoof treatment arrangement arranged to spray a liquid onto hooves of animals while they are stationary in a stall of an animal arrangement includes an identification system configured to identify animals, an automatic detector arrangement configured to determine the hoof status for animals, an automatic spray device, and a control arrangement. The control arrangement is operatively connected to an information database of the animal arrangement, which includes animal specific information for a plurality of animals housed in the animal arrangement; the identification system, to obtain information regarding the identity of each of the plurality of animals; the automatic detector arrangement, to obtain information regarding the hoof status for each of the identified animals; and the automatic spray device, to control the automatic spray device.

A milking system for milking a dairy animal comprises teat cups, a robot arm with actuators, for connecting the teat cups to teats of the dairy animal, and a control device in order to reach and/or maintain a desired position of the robot arm, by adjustment of a respective adjusting force parameter exerted by the actuators. The control device is configured to adjust a selectable compliance of the robot arm, wherein the compliance is a reaction of the robot arm to an external force which is exerted on the robot arm, such as a kick. This compliance is a function of the external force or of an animal identity. Thus, the behaviour of the robot arm can be adapted, such as, under otherwise unchanged circumstances, more or earlier yielding in the case of sensitive animals, and, conversely, less in the case of playful animals.

In picking up tools in an automatic milking arrangement, the positions of the tools are determined by registering, via a camera at an origin location, three-dimensional image data representing the tools whose positions are to be determined. Using an algorithm involving matching the image data against reference data, tool candidates are identified in the three-dimensional image data. A respective position is calculated for the tools based on the origin location and data expressing respective distances from the origin location to each of the identified tool candidates. It is presumed that the tools have predefined locations relative to one another. Therefore, any second tool candidate is disregarded, which is detected at a separation distance from a first tool candidate when the separation distance exceeds a first threshold distance in relation to the predefined relative locations.

The positions of the tools in an automatic milking arrangement are determined by registering, via a camera at an origin location, three-dimensional image data representing the tools whose positions are to be determined. Using an algorithm involving matching the image data against reference data, tool candidates are identified in the three-dimensional image data. A respective position is calculated for the tools based on the origin location and data expressing respective distances from the origin location to each of the identified tool candidates. It is presumed that the tools are arranged according to a spatially even distribution relative to one another. Therefore, any tool candidate is disregarded, which is detected at such a position that the position for the candidate deviates from the spatially even distribution.

The milking apparatus includes a cluster (4) connected to a retraction line (10), and a cylinder (11) having a piston (13) being movable between first and second end positions. The piston acts on the retraction line to move the cluster to a retracted rest position when moved to the second end position, and to permit the cluster to be moved to an active milking position when the piston is in the first end position. A switch device (30) may alternate between a first state and a second state. The retraction line permits the switch device to change from the first state to the second state when a movement of the cluster from the retracted rest position is initiated. The switch device initiates in the second state supply of a pressurized medium to the cylinder to force the piston to the first end position.

The present invention discloses a free dome range (FDR) where dairy animals have a free access to their stall to concurrently eat and to be milked. The FDR comprises a plurality of stalls; at least one of said stalls is characterized by a front side and rear opposite side into which a dairy animal is at least temporarily accommodated, head fronting said front side; a plurality of main living areas (MLAs); at least one of said MLAs is in connection with at least one of said stalls by means a plurality of gates. The FDR further comprising a substantially horizontally positioned elevated rail system comprising a plurality of elevated rails, and a plurality of mobile milking units (MMUs), each of said MMUs is configured to transport on said elevated rail to a dairy animal at its stall, and milk the animal while it is eating.