Disclosed is a method for determining of fat content of milk having variable solids fractions and flowing with variable gas content in a pipeline. The method includes ascertaining a velocity of sound and an average density value for the milk based on eigenfrequencies of at least two bending oscillation wanted modes of measuring tubes of a densimeter arranged in the pipeline. The method further includes ascertaining a static pressure in the pipeline; a gas volume fraction based on the velocity of sound; the average density; the pressure; a density of the milk without gas content based on the average density and the gas volume fraction; and a permittivity of the milk based on a propagation velocity and/or an absorption of microwaves in the milk. The fat fraction is calculated based on the density of the milk without gas content and on the effective permittivity.

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.

The present patent application provides an instrument for mastitis detection and analysis, comprising: a computing module, a conductivity detection module and a temperature sensor; the conductivity detection module is used to detect the conductivity of a sample, and is used to send the detected sample conductivity data to the computing module; the temperature sensor is used to detect the sample temperature, and is used to send the sample temperature data to the computing module; the computing module is used to calculate the received sample conductivity and the sample temperature through a detection algorithm, and is used to detect and analyze the mastitis of the sample through the detection algorithm. The instrument for mastitis detection and analysis is convenient to be carried and easy-to-use, it can be quickly immerged into a milk sample to complete the detection, and the detection result can be obtained quickly.

The present patent application provides an instrument for mastitis detection and analysis, comprising: a computing module, a conductivity detection module and a temperature sensor; the conductivity detection module is used to detect the conductivity of a sample, and is used to send the detected sample conductivity data to the computing module; the temperature sensor is used to detect the sample temperature, and is used to send the sample temperature data to the computing module; the computing module is used to calculate the received sample conductivity and the sample temperature through a detection algorithm, and is used to detect and analyze the mastitis of the sample through the detection algorithm. The instrument for mastitis detection and analysis is convenient to be carried and easy-to-use, it can be quickly immerged into a milk sample to complete the detection, and the detection result can be obtained quickly.

Method for continuous determining of fat content of milk having variable solids fractions and flowing with variable gas content in a pipeline, comprising: ascertaining a value for velocity of sound and an average density value for milk flowing in the pipeline based on eigenfrequencies of at least two bending oscillation wanted modes of measuring tubes of a densimeter arranged in the pipeline; ascertaining a value for static pressure in the pipeline by means of a pressure sensor connected to the pipeline; ascertaining a value for gas volume fraction based on the value for the velocity of sound, the value for the average density and the value for the pressure; ascertaining a value of density of milk flowing in the pipeline without gas content based on the value for the average density and based on the value for the gas volume fraction; ascertaining a value for permittivity of milk flowing in the pipeline based on at least one measuring of propagation velocity and/or absorption of microwaves in the milk by means of a microwave sensor arranged in the pipeline; and calculating fat fraction based on the value of the density of the milk flowing in the pipeline without gas content and the value for the effective permittivity.

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 Health Management System for automatic monitoring of dairy animal's health. The system including a method for mastitis detection through, at least, electrical conductivity measurement of milk powered by artificial intelligence analysis. In addition, an apparatus for automatically measuring electrical conductivity and temperature of milk, and milking time length, all from each teat of the animal separately. All information is transmitted for registering and statistics development remotely.

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.