A milk analyser system is provided for detecting the presence of a biomarker, the system comprising: a colorimetric sensor which is arranged to change colour in the presence of a biomarker to be detected; and an optically transparent container which contains the sensor, the container being openable in use to allow milk received by the system to pass over the sensor in order to provide an indication of the biomarker in the milk, any change in colour in the sensor being detectable by viewing the sensor through the container.

An inline analyzer for a milking machine system includes an outer body having a central axis, a fluid input channel, an upper cover attached to the fluid input channel, a central portion attached to the upper cover, a lower portion attached to the central portion, and a fluid output channel attached to the lower portion, wherein the fluid input channel, the central portion and the fluid output channel each have a hollow central channel. A float portion is disposed loosely within the outer body and is free to move axially along the central axis such that milk flows around the float portion. Electrode(s) extend through an upper portion of the float portion. A battery, processor(s), memory and actuator are disposed within float portion. The actuator causes the float portion to move axially along the outer body central to regulate the flow of milk through the outer body.

An inline analyzer for a milking machine system includes an outer body having a central axis, a fluid input channel, an upper cover attached to the fluid input channel, a central portion attached to the upper cover, a lower portion attached to the central portion, and a fluid output channel attached to the lower portion, wherein the fluid input channel, the central portion and the fluid output channel each have a hollow central channel. A float portion is disposed loosely within the outer body and is free to move axially along the central axis such that milk flows around the float portion. Electrode(s) extend through an upper portion of the float portion. A battery, processor(s), memory and actuator are disposed within float portion. The actuator causes the float portion to move axially along the outer body central to regulate the flow of milk through the outer body.

A milking system for milking a dairy animal includes a milking cup and a measuring chamber which is in flow communication with the milking cup for the obtained milk where the chamber has a sensor system for measuring at least one property of the milk. The sensor system includes at least three optical sensor devices, each configured to measure values of a property of the milk, and a sensor control unit for actuating the sensor system and for processing the measured values. The sensor control unit is configured to repeatedly select one of the sensor devices. Two of the optical sensor devices are identical, and the sensor system is configured to in each case measure the local value of the property of the milk and to determine a value of the at least one property of the milk in the measuring chamber on the basis of the values measured locally.

An inline analyzer for a milking machine system includes an outer body having a central axis, a fluid input channel, an upper cover attached to the fluid input channel, a central portion attached to the upper cover, a lower portion attached to the central portion, and a fluid output channel attached to the lower portion, wherein the fluid input channel, the central portion and the fluid output channel each have a hollow central channel. A float portion is disposed loosely within the outer body and is free to move axially along the central axis such that milk flows around the float portion. Electrode(s) extend through an upper portion of the float portion. A battery, processor(s), memory and actuator are disposed within float portion. The actuator causes the float portion to move axially along the outer body central to regulate the flow of milk through the outer body.

An inline analyzer for a milking machine system includes an outer body having a central axis, a fluid input channel, an upper cover attached to the fluid input channel, a central portion attached to the upper cover, a lower portion attached to the central portion, and a fluid output channel attached to the lower portion, wherein the fluid input channel, the central portion and the fluid output channel each have a hollow central channel. A float portion is disposed loosely within the outer body and is free to move axially along the central axis such that milk flows around the float portion. Electrode(s) extend through an upper portion of the float portion. A battery, processor(s), memory and actuator are disposed within float portion. The actuator causes the float portion to move axially along the outer body central to regulate the flow of milk through the outer body.

A milking system with a milking device, a milking control, a milk line in fluid connection with the milking device, and a sampling and analysis device to take a sample of the milk from the milk line and to analyse milk from the sample are disclosed. The milking control is arranged to control the milking device on the basis of the analysis. The sampling and analysis device includes a control unit, a tape reel provided with a tape that is lengthwise provided with a series of consecutive reagent pads that provide a detectable response in the presence of a substance in the sample, a tape mover to move the tape, a dosing device to supply a part of the sample onto a reagent pad on the tape, and a camera to obtain an image of the reagent pad supplied with the droplet, and an analysis device to analyse the obtained images to provide to the milking control device an indication of a presence or concentration of said substance. The camera has a field of view that contains a plurality of reagent pads of the series of consecutive reagent pads. This allows to observe the reaction in the reagent pad for a much longer time. In turn, this allows to use much less reagent material, such as expensive enzymes, in the pads. It is particularly useful when observing double layer reagent types.

In one aspect, the invention provides a sampling apparatus for taking a representative milk sample in a predetermined quantity range from a conveying line in which milk is conveyed at conveying intervals of unknown length. The sampling apparatus comprises a pump, a controller of the pump, and a sample container connecting element connecting member in communication with the pump, wherein the controller is configured based on the predetermined quantity range and a measured quantity indicating a flow rate of milk conveyed in the conveying line and/or a predetermined quantity indicating a total quantity of milk to be conveyed through the conveying line in a conveying interval, to control a pulsed operation of the pump in a conveying interval, wherein the pump conveys a discrete sample subset along a first conveying direction of the pump during the pulsed operation in each sample pulse interval, and wherein the predetermined quantity range is greater than or equal to a total quantity corresponding to a total number of discrete sample subsets in the conveying interval.

A distribution unit for milk samples includes a flow passage, a valve controlled milk inlet port through which milk is delivered to the flow passage, a pump port through which a sampling pump communicates with the flow passage, and at least two valve controlled milk sampling outlet ports through which milk samples are delivered from the flow passage to a respective milk sample analyzing unit. The flow passage has a longitudinal extension between a first end and a second end, and the milk sampling outlet ports are connected to the flow passage in positions located between the connection position of the milk inlet port and the connection position of the pump port.

An inline analyzer for a milking machine system includes an outer body having a central axis, a fluid input channel, an upper cover attached to the fluid input channel, a central portion attached to the upper cover, a lower portion attached to the central portion, and a fluid output channel attached to the lower portion, wherein the fluid input channel, the central portion and the fluid output channel each have a hollow central channel. A float portion is disposed loosely within the outer body and is free to move axially along the central axis such that milk flows around the float portion. Electrode(s) extend through an upper portion of the float portion. A battery, processor(s), memory and actuator are disposed within float portion. The actuator causes the float portion to move axially along the outer body central to regulate the flow of milk through the outer body.