A milking system for milking a dairy animal includes a milking cup to be attached to a teat of the dairy animal and milking the milk, and an electronic component. The electronic component includes a sensor which is arranged in or on the milking cup for measuring a value of a variable related to the milking, a transmitter for transmitting the measured values, and a power supply for supplying the sensor and/or the transmitter with electrical energy. The power supply may include an inductive power supply with a first coil component and a second coil component, where the first coil component and the electronic component are electrically connected to each other, and where the second coil component is electrically directly connectable to an external source of electrical energy. The milking system also includes a fastening means which holds the first coil component and the second coil component together.

A milking system for milking a dairy animal includes a milking cup to be attached to a teat of the dairy animal and milking the milk, and an electronic component. The electronic component includes a sensor which is arranged in or on the milking cup for measuring a value of a variable related to the milking, a transmitter for transmitting the measured values, and a power supply for supplying the sensor and/or the transmitter with electrical energy. The power supply may include an inductive power supply with a first coil component and a second coil component, where the first coil component and the electronic component are electrically connected to each other, and where the second coil component is electrically directly connectable to an external source of electrical energy. The milking system also includes a fastening means which holds the first coil component and the second coil component together.

A differential vacuum system for use with a milking system. The differential vacuum system is configured to modulate the fluid pressure in the pulsation volume to cause a milking operation on a teat of an animal that is inserted into the bore of a liner. The pulsation cycle includes an “on” phase to open the liner and thereby enable milk flow from the teat, and an “off” phase in which the pulsation volume is at an increased pressure relative to the “on” phase to close the liner bore to thereby stop milk flow from the teat. The differential vacuum system controls the maximum vacuum applied to the pulsation volume to exceed the maximum vacuum applied to the liner bore.

A differential vacuum system for use with a milking system. The differential vacuum system is configured to modulate the fluid pressure in the pulsation volume to cause a milking operation on a teat of an animal that is inserted into the bore of a liner. The pulsation cycle includes an “on” phase to open the liner and thereby enable milk flow from the teat, and an “off” phase in which the pulsation volume is at an increased pressure relative to the “on” phase to close the liner bore to thereby stop milk flow from the teat. The differential vacuum system controls the maximum vacuum applied to the pulsation volume to exceed the maximum vacuum applied to the liner bore.

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.

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.

An automatic milking machine extracts milk from the teats of an animal by applying a milking vacuum to a respective teat receiving cavity of a teat cup (111, 112, 113, 114) each in which one of the teats is located during a milking session. The milking session includes a boost phase (TBOOST) and is concluded by an exit phase (TEXIT). During the boost phase (TBOOST), the milking vacuum is applied at an elevated pressure level. During the exit phase, the milking vacuum is applied at one or more levels, each of which is lower than the elevated pressure level. The operation of the automatic milking machine transitions from the boost phase (TBOOST) to the exit phase (TEXIT) when (t2) a temporal criterion is fulfilled.

An automatic milking machine extracts milk from the teats of an animal by applying a milking vacuum to a respective teat receiving cavity of a teat cup (111, 112, 113, 114) each in which one of the teats is located during a milking session. The milking session includes a boost phase (TBOOST) and is concluded by an exit phase (TEXIT). During the boost phase (TBOOST), the milking vacuum is applied at an elevated pressure level. During the exit phase, the milking vacuum is applied at one or more levels, each of which is lower than the elevated pressure level. The operation of the automatic milking machine transitions from the boost phase (TBOOST) to the exit phase (TEXIT) when (t2) a temporal criterion is fulfilled.

A milking system includes a device to sample and analyse a milk sample, including a control unit, a sample supply line connected to the milk line, a pump to control the sample flow, an optical radiation source, and an optical sensor device to detect and analyse optical radiation coming from the reagent pad with said sample, to provide an indication of a substance in the sample, a tape mover to move and unwind the tape from the tape reel, and a pump drive, external to the cassette, and releasably operably connected to the pump device for driving the pump device. The sampling and analysis device also includes a cassette with a sample receiving line, releasably connected to the sample supply line by a liquid connector, and arranged to receive the sample from the sample supply line, a tape reel with a tape that includes a base tape layer and a series of separate reagent pads, and a dosing device to provide a droplet of the sample onto a reagent pad. The dosing device includes a nozzle in fluid connection with the sample receiving line, and a nozzle mover arranged to move the nozzle in at least a longitudinal direction. The cassette is replaceably received in the milking system. Hereby, a large number of parts that are subject to wear and contamination by milk residues are exchanged regularly, which improves measurement reliability and accuracy.

A control arrangement and a control module for a milking position for milking a dairy animal includes a casing forming an inner space enclosing a printed circuit board incorporating a control system for controlling and supervising at least some functions of the milking position. A communication area is provided on a front side of the printed circuit board and communicates with the control system. The casing includes an inner front plate. The front side of the printed circuit board is attached to a rear side of the inner front plate by a transparent adhering substance so that a part of the printed circuit board projects from the rear side of the inner front plate. The inner front plate permits access to the communication area. The part of the printed circuit board is embedded in a block of plastic material.