A dairy animal treatment system for fully automatically performing a teat-related operation on a dairy animal, including a treatment location for receiving the dairy animal, a treatment device which is configured for performing the teat-related operation on the dairy animal, a teat-detecting device for determining a teat position of the teat of the dairy animal, a dairy animal position-determining device for repeatedly determining an animal position of said dairy animal with respect to the milking stall and/or the dairy animal position-determining device, a robot arm for moving the treatment device towards the teat, and a control device which is configured to control the robot arm on the basis of the determined animal position and the determined teat position. The dairy animal position-determining device comprises a mm-wavelength radar device which transmits a radar signal having a wavelength in the mm range.

A milking cluster used for milking a dairy animal in a milking parlor, the milking cluster including a teat cup unit, a teat cup, a drive device, a hose arrangement joined to the teat cup, a hose guide engaging the hose arrangement, and the hose guide includes a plurality of hose-engaging rollers.

A voluntary milking system and method for treating dairy livestock having fore legs and hind legs, wherein the system comprises milking stalls voluntarily accessible to animals that are milked by mobile units configured to travel between the fore and hind legs of the animal.

A valve device that transitions between the pressure and vacuum phases for the purpose of milking animals. The improvement provides a pulsation output with a vacuum supply duration less than that of atmospheric air pressure supply duration.

A space divider of a milking parlor arrangement for at least one milking parlor for milking milk-producing animals, wherein the space divider is arranged approximately parallel to a longitudinal axis of the animal to be milked, has an arm device having a milking cluster, which can be adjusted from a parking position to a working position and back. The arm device is arranged with the milking cluster in the parking position in the space divider and can be adjusted into the working position laterally to the animal to be milked between the front and rear legs thereof in fully automatic operation or semiautomatic operation. The space divider is designed in such a way that no additional space is required between adjacent animals, so that many animals can be milked in a milking parlor arrangement while the smallest possible amount of space is required.

A space divider (4) of a milking parlor arrangement (1, 1, 1, 1) for at least one milking parlor (3) for milking milk-producing animals (T), wherein the space divider (4) is arranged approximately parallel to a longitudinal axis of the animal (T) to be milked, has an arm device (6) having a milking cluster (5), which can be adjusted from a parking position to a working position and back. The arm device (6) is arranged with the milking cluster (5) in the parking position in the space divider (4) and can be adjusted into the working position laterally to the animal (T) to be milked between the front and rear legs thereof in fully automatic operation or semi-automatic operation. The space divider (4) is designed in such a way that no additional space is required between adjacent animals (T), so that many animals (T) can be milked in a milking parlor arrangement (1, 1, 1, 1) while the smallest possible amount of space is required.

A valve device that transitions between the pressure and vacuum phases for the purpose of milking animals. The improvement provides a pulsation output with a vacuum supply duration less than that of atmospheric air pressure supply duration.

A leg (205) detection system comprising: a robotic arm (200) comprising a gripping portion (208) for holding a teat cup (203, 210) for attaching to a teat (1102, 1104, 1106, 1108, 203S, 203) of a dairy livestock (200, 202, 203); an imaging system coupled to the robotic arm (200) and configured to capture a first three-dimensional (3D) image (138, 2400, 2500) of a rearview of the dairy livestock (200, 202, 203) in a stall (402), the imaging system comprising a 3D camera (136, 138) or a laser (132), wherein each pixel of the first 3D image (138, 2400, 2500) is associated with a depth value; one or more memory (104) devices configured to store a reference (3D) 3D image (138, 2400, 2500) of the stall (402) without any dairy livestock (200, 202, 203); and a processor (102) communicatively coupled to the imaging system and the one or more memory (104) devices, the processor (102) configured to: access the first 3D image (138, 2400, 2500) and the reference (3D) 3D image (138, 2400, 2500); subtract the first 3D image (138, 2400, 2500) from the reference (3D) 3D image (138, 2400, 2500) to produce a second 3D image (138, 2400, 2500); perform morphological image (138, 2400, 2500) processing on the second 3D image (138, 2400, 2500) to produce a third 3D image (138, 2400, 2500); perform image (138, 2400, 2500) thresholding on the third 3D image (138, 2400, 2500) to produce a fourth 3D image (138, 2400, 2500); cluster (2616, 2618, 2626, 2628) data from the fourth 3D image (138, 2400, 2500); identify, using the clustered data from the fourth 3D image (138, 2400, 2500), one or more legs (205) of the dairy livestock (200, 202, 203); and provide instructions for movements of the robotic arm (200) to avoid the identified one or more legs (205) while attaching the teat cup (203, 210) to the teat (1102, 1104, 1106, 1108, 203S, 203) of the dairy livestock (200, 202, 203).

A vision system that includes a robotic arm and a three-dimensional (3D) camera operably coupled to a processor. The processor is configured to acquire a 3D image and identify a teat of the dairy livestock within the 3D image. The processor is further configured to determine a distance between a portion of a robotic arm and an approach vector for the teat, to compare the distance between the portion of the robotic arm and the approach vector for the teat and the attachment range threshold value, and to send instructions to the robotic arm based on the comparison.

A robot milking device for fully automatic milking includes milking means with a plurality of teat cups, a robot arm for moving the teat cups and connecting these to the teats, and provided with one teat cup holder for each teat cup, for removably placing the teat cup thereon in a rest state, a teat position determination device for determining teat positions, and a control device for the robot milking device and for moving the robot arm on the basis of the determined teat positions. The control device is configured to move the robot arm into a rest position during milking and to detect a cup separation signal which indicates that no teat cup is attached to at least one front teat. The control device is furthermore configured to adapt the rest position as a function of the cup separation signal.