A milking system for milking a dairy animal includes a milking cup for obtaining milk, a measuring chamber which is in flow communication with the milking cup for at least temporarily containing the obtained milk, and having a sensor device for measuring at least one property of the milk. The sensor device comprises at least three mutually separate electrodes for measuring values of a first milk property using an electrical and/or electromagnetic variable, and a sensor control unit for actuating the sensor device and for processing the measured values. The sensor control unit is configured to repeatedly select a pair of the electrodes in a targeted manner, the pair comprising a first electrode and a second electrode which differs from the first electrode. The sensor device is configured to measure the value of the variable between the electrodes, and to determine the value of the at least one milk property.

A milking system for milking a dairy animal includes a milking cup for obtaining milk, a measuring chamber which is in flow communication with the milking cup for at least temporarily containing the obtained milk, and having a sensor device for measuring at least one property of the milk. The sensor device comprises at least three mutually separate electrodes for measuring values of a first milk property using an electrical and/or electromagnetic variable, and a sensor control unit for actuating the sensor device and for processing the measured values. The sensor control unit is configured to repeatedly select a pair of the electrodes in a targeted manner, the pair comprising a first electrode and a second electrode which differs from the first electrode. The sensor device is configured to measure the value of the variable between the electrodes, and to determine the value of the at least one milk property.

There is provided a teat cup (1) comprising a flexible liner (3) for engaging about a teat of an animal to be milked. The liner has a head portion (7) at one end of the liner and a milk discharge passageway (12) at another end of the liner. The head portion is provided with a mouth (9) through which the teat is engageable with the liner, and an injector (18) for injecting fluid into the head portion of the liner. The injector comprises a gravity biased diverter that controls, based on an orientation of the teat cup, an injection direction (FLT, FLF) in which the fluid is injected into the head portion. There is further provided a method for milking an animal using the teat cup.

There is provided a teat cup (1) comprising a flexible liner (3) for engaging about a teat of an animal to be milked. The liner has a head portion (7) at one end of the liner and a milk discharge passageway (12) at another end of the liner. The head portion is provided with a mouth (9) through which the teat is engageable with the liner, and an injector (18) for injecting fluid into the head portion of the liner. The injector comprises a gravity biased diverter that controls, based on an orientation of the teat cup, an injection direction (FLT, FLF) in which the fluid is injected into the head portion. There is further provided a method for milking an animal using the teat cup.

A protective device for a milking cup including a milking cup part enclosing a portion of the milking cup at a location of a connection, the milking cup part including a wall. The milking cup part includes an opening in the wall for passing through at least one of a milk discharge line and pulsating line, and a single-part or multipart line part connectable to form a circumferential wall for enclosing at least a part of the at least one of the milk discharge line and the pulsating line. The line part is connected to the milking cup part around the opening in the wall, wherein the line part, from the milking cup part, successively encloses first, second, and third parts, wherein at least the third part is dimensionally stable and the second part is, for example, at least ten times more flexible than the third part.

A protective device for a milking cup including a milking cup part enclosing a portion of the milking cup at a location of a connection, the milking cup part including a wall. The milking cup part includes an opening in the wall for passing through at least one of a milk discharge line and pulsating line, and a single-part or multipart line part connectable to form a circumferential wall for enclosing at least a part of the at least one of the milk discharge line and the pulsating line. The line part is connected to the milking cup part around the opening in the wall, wherein the line part, from the milking cup part, successively encloses first, second, and third parts, wherein at least the third part is dimensionally stable and the second part is, for example, at least ten times more flexible than the third part.

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, 2038, 203) of a diary 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) 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 teat cup sleeve constructed from two connectable sleeve parts, a modular teat cup system and a corresponding method for the application of a modular teat cup sleeve are provided. The modular design of the teat cup sleeve allows a versatile adaptation of one teat cup to different milking conditions, for example by changing one sleeve part while retaining the other sleeve part with the necessary connection arrangement.

A teat cup sleeve constructed from two connectable sleeve parts, a modular teat cup system and a corresponding method for the application of a modular teat cup sleeve are provided. The modular design of the teat cup sleeve allows a versatile adaptation of one teat cup to different milking conditions, for example by changing one sleeve part while retaining the other sleeve part with the necessary connection arrangement.

A teat cleaning cup (130) for cleaning a teat (120) includes a teat cleaner (300) having an inner body (270) forming a central cavity (280) for enclosing the teat (120), the inner body (270) including an inner surface (271), an outer surface (272), and a set of apertures (275) extending from the outer surface (272) to the inner surface (271); an exterior part (220) enclosing the inner body (270); a set of channels (291, 292), which set of channels (291, 292) connects to the set of apertures (275); a lower part (230) removably attached to the teat cleaner (300), which lower part (230) includes at least one cleaning liquid valve (240, 260), and a drain (250); and a seal (235) configured to distribute liquid from the cleaning liquid valve (240, 260) into the set of channels (291, 292).