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 method for operating a valve, comprises directing fluid flow through a housing of the valve, wherein the fluid flows into the housing through a housing inlet and flows out of the housing through a housing outlet. The method continues by directing a first electric current into a solenoid coupled to the housing to generate a first magnetic field, wherein the first magnetic field exerts a force upon a plunger positioned inside the housing and causes the plunger to magnetically connect to a magnet. The method continues by directing a second electrical current into the solenoid to generate a second magnetic field, wherein the second magnetic field exerts a force upon the plunger causing the plunger to disconnect from the magnet and engage with the housing outlet. Fluid flows into the inlet through a milking hose, and fluid flows out of the outlet into a milking pipeline.

A safety valve for a cleaning device for a milking installation for milking milk-providing animals, including a first block valve with an input, a second block valve with an output, a bleed valve with a bleed output, a piston rod and a drive unit, wherein the safety valve is movable from a blocking position, in which the first block valve and the second block valve are closed in order to block the input and the output and in which the bleed valve is opened in order to connect the bleed output to a connection, into a pass-through position, in which the first block valve and the second block valve are opened in order to connect the input to the output via the connection and in which the bleed valve is closed in order to block the bleed output, and back. The first block valve, the second block valve and the bleed valve of the safety valve are designed as seat valves with a common piston plate.

A safety valve arrangement and method, having an upstream block valve, a downstream block valve, and a pressure monitored galley between the upstream valve and the downstream valve.

A teat dip fluid manifold and methods for distributing teat dip fluids, and including redundant valve sets and pressure monitoring between valve pairs to determine valve condition.

An apparatus that includes a housing with an input port and a first output port. A piston is disposed within a bore of the housing and includes a bypass via disposed transversely within the bore and a bypass tube disposed longitudinally within the bore. The bypass tube is configured to provide a flow path from the bypass via to a second output port on the bypass tube. The piston includes a sleeve disposed concentrically around the bypass tube. An interior chamber is defined by an exterior surface of the sleeve and an interior surface of the bore of the housing. The piston is configurable between a first configuration that provides a first flow path between the input port and the first output port via the interior chamber and a second configuration that provides a second flow path between the input port and the second output port via the bypass tube.

A milking system includes a milking apparatus for milking of dairy animals, and a plurality of wearing parts, inclusive of teat liners and/or milk lines and/or pulsation lines. The system further includes a computer system configured to control and/or monitor the milking apparatus, and to generate a signal which indicates that one of the wearing parts should be replaced and provides a characterization of that wearing part. The milking system further includes a 3D printer operatively connected to the computer system and configured to print the characterized part on the basis of the generated signal. Thus it is not necessary to keep an unnecessarily large stock of spare parts, but it becomes possible to directly provide the spare parts quickly, cheaply and with less chance of errors. Moreover, it is thus possible to tailor the parts, especially teat liners, to animals.

A milking system includes a milking apparatus for milking of dairy animals, and a plurality of wearing parts, inclusive of teat liners and/or milk lines and/or pulsation lines. The system further includes a computer system configured to control and/or monitor the milking apparatus, and to generate a signal which indicates that one of the wearing parts should be replaced and provides a characterization of that wearing part. The milking system further includes a 3D printer operatively connected to the computer system and configured to print the characterized part on the basis of the generated signal. Thus it is not necessary to keep an unnecessarily large stock of spare parts, but it becomes possible to directly provide the spare parts quickly, cheaply and with less chance of errors. Moreover, it is thus possible to tailor the parts, especially teat liners, to animals.

The invention provides a milking device comprising at least one milking cup with a teat space and a pulsation space, a pulsator connected by means of a pulsation line to the pulsation space of the milking cup and provided with a vacuum source, a vacuum line provided with a first controllable valve between the vacuum source and the pulsation line, an aeration line provided with a second controllable valve between the pulsation line and a source of higher pressure, and a pulsator control system for the first and second valves, wherein the pulsator control system comprises a flushing mode for opening and holding open the first and second valves during at least a predefined flushing time which is at least as long as and preferably longer than the pulsation period. In this way it is possible to have both valves open simultaneously and the pulsator will draw in air from the environment in an initially unhindered flow. This flow may be used for example to flush the system with air (blow through) but also for example to measure the air flow and/or pressure drops in the system, and on the basis thereof to determine the degree of soiling of the system.

Milking clusters for a miling installation have four teat cups, each teat cup having a cup housing and a teat cup liner with a top region and a suction region. A connection for a milk tube is arranged at the cup bottom or at the end of the suction region of the teat cup liner. A mouth portion of a sterile air pressure line is arranged in the top region of the teat cup liner, through which pressure line sterile air is introduced at a volumetric flow rate greater than a fluid aspiration volumetric flow rate at the milk tube, such that a sterile air blanket is established in the top region of the teat cup liner. The milking clusters with the cup liner and sterile air blanket prevent milked milk from being contaminated by contaminants and microorganisms from the shed air, extending storage life for untreated raw milk.