The present invention relates to preparing dairy animal teats for being milked, and more particularly to teat preparation, rinsing, and milking that all take place in a milking machine teat cup liner. Such a method includes: applying a teat sanitizer to the teat; injecting air into the liner to force the teat sanitizer toward a waste milk line connected to the liner; pulsating the liner at a first pulsation rate; drawing a rinsing milk from the teat; directing the teat sanitizer, the air, and the rinsing fluid to the waste milk line; pulsating the liner at a second pulsation rate to draw additional milk from the teat; and directing the additional milk to a good milk line.

The present invention relates to preparing dairy animal teats for being milked, and more particularly to teat preparation, rinsing, and milking that all take place in a milking machine teat cup liner. Such a method includes: applying a teat sanitizer to the teat; injecting air into the liner to force the teat sanitizer toward a waste milk line connected to the liner; pulsating the liner at a first pulsation rate; drawing a rinsing milk from the teat; directing the teat sanitizer, the air, and the rinsing fluid to the waste milk line; pulsating the liner at a second pulsation rate to draw additional milk from the teat; and directing the additional milk to a good milk line.

Improving milking system performance through the incorporation of a source of greater than atmospheric pressure air into a pulsator while limiting total pressure in the teat cup. The system is further improved by providing an improved supply of regulated vacuum to the milking cluster throughout the milking process. The system is further improved with a monitoring and detecting the functional failure of the pulsation assemblies. Additional system improvements are provided with the addition of a fresh air valve assembly, a wireless method of regulating vacuum levels and the remote location of a pulsator assembly in a basement style parlor.

Improving milking system performance through the incorporation of a source of greater than atmospheric pressure air into a pulsator while limiting total pressure in the teat cup. The system is further improved by providing an improved supply of regulated vacuum to the milking cluster throughout the milking process. The system is further improved with a monitoring and detecting the functional failure of the pulsation assemblies. Additional system improvements are provided with the addition of a fresh air valve assembly, a wireless method of regulating vacuum levels and the remote location of a pulsator assembly in a basement style parlor.

In order to avoid negative changes in the teat ends of a cow, in particular to avoid hyperkeratoses, the invention proposes a method for operating a milking system in which at least one of the parameters from total pressure per cycle, minimum total pressure per cycle or the ratio of total suction to total pressure is determined for at least one animal of a herd during at least one part of a milking process, and is compared with at least one reference value.

In order to avoid negative changes in the teat ends of a cow, in particular to avoid hyperkeratoses, the invention proposes a method for operating a milking system in which at least one of the parameters from total pressure per cycle, minimum total pressure per cycle or the ratio of total suction to total pressure is determined for at least one animal of a herd during at least one part of a milking process, and is compared with at least one reference value.

A system comprising a teat preparation cup coupled to a vacuum pump. A first pressure sensor measures the vacuum level of the vacuum pump. A second pressure sensor measures vacuum level inside the preparation cup. The system further comprises a controller comprising an interface, a memory, and a processor. The processor determines if the vacuum pump has sufficient vacuum level and communicates instructions to induce a partial vacuum in the teat preparation cup. The processor determines if the teat preparation cup has a vacuum level greater than a vacuum threshold value and when this condition is achieved, communicates instructions to initiate a teat preparation cycle comprising allowing fluid flowing from a fluid source container through the teat preparation cup into a fluid disposal container.

A system comprising a teat preparation cup coupled to a vacuum pump. A first pressure sensor measures the vacuum level of the vacuum pump. A second pressure sensor measures vacuum level inside the preparation cup. The system further comprises a controller comprising an interface, a memory, and a processor. The processor determines if the vacuum pump has sufficient vacuum level and communicates instructions to induce a partial vacuum in the teat preparation cup. The processor determines if the teat preparation cup has a vacuum level greater than a vacuum threshold value and when this condition is achieved, communicates instructions to initiate a teat preparation cycle comprising allowing fluid flowing from a fluid source container through the teat preparation cup into a fluid disposal container.

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 milking system includes an assembly, a controller, and a milking cluster configured to attach to one or more teats of a livestock. The assembly includes a clevis, a piston, a pulley system, and a sensor. The clevis includes a first member, a second member, a base member, and a cylinder. The cylinder is coupled to the base member. The piston is positioned at least partially within the cylinder, and is configured to move within the cylinder. The pulley system of the assembly includes a cord configured to be coupled to the milking cluster. The assembly includes a sensor configured to generate a displacement signal in response to detecting that a portion of the clevis is within a predefined distance of the sensor.