A milking cup comprising a body having a top portion and a bottom portion. The top portion has a first lip formed thereon and the bottom portion has a second lip formed thereon. The first lip and the second lip are separated by a distance. The milking cup further comprises a rotating shell positioned between and secured by the first lip and the second lip, wherein the rotating shell encircles the body and is operable to rotate around the body independently of the movement of the other portions of the body. The rotating shell has a length that corresponds to the distance between the first lip and the second lip.

A milking cup comprising a body having a top portion and a bottom portion. The top portion has a first lip formed thereon and the bottom portion has a second lip formed thereon. The first lip and the second lip are separated by a distance. The milking cup further comprises a rotating shell positioned between and secured by the first lip and the second lip, wherein the rotating shell encircles the body and is operable to rotate around the body independently of the movement of the other portions of the body. The rotating shell has a length that corresponds to the distance between the first lip and the second lip.

A dipping device for a mechanical milking system comprises at least one liner defining an accommodation space for a teat. The liner has a milk evacuation opening and a collecting claw. For each liner, a connector connects the liner to the collecting claw. The dipping device further includes a source of a dipping product, an injunction interface mounted on the collecting claw, and an injection tube for each liner. The injection tube extends from the interface and substantially to the teat accommodation space, running inside of the connector and through the evacuation opening.

A dipping device for a mechanical milking system comprises at least one liner defining an accommodation space for a teat. The liner has a milk evacuation opening and a collecting claw. For each liner, a connector connects the liner to the collecting claw. The dipping device further includes a source of a dipping product, an injunction interface mounted on the collecting claw, and an injection tube for each liner. The injection tube extends from the interface and substantially to the teat accommodation space, running inside of the connector and through the evacuation opening.

A dipping device for a mechanical milking system comprises at least one liner defining an accommodation space for a teat. The liner has a milk evacuation opening and a collecting claw. For each liner, a connector connects the liner to the collecting claw. The dipping device further includes a source of a dipping product, an injunction interface mounted on the collecting claw, and an injection tube for each liner. The injection tube extends from the interface and substantially to the teat accommodation space, running inside of the connector and through the evacuation opening.

A dipping device for a mechanical milking system comprises at least one liner defining an accommodation space for a teat. The liner has a milk evacuation opening and a collecting claw. For each liner, a connector connects the liner to the collecting claw. The dipping device further includes a source of a dipping product, an injunction interface mounted on the collecting claw, and an injection tube for each liner. The injection tube extends from the interface and substantially to the teat accommodation space, running inside of the connector and through the evacuation opening.

A milking cup comprising a body having a top portion and a bottom portion. The top portion has a first lip formed thereon and the bottom portion has a second lip formed thereon. The first lip and the second lip are separated by a distance. The milking cup further comprises a rotating shell positioned between and secured by the first lip and the second lip, wherein the rotating shell encircles the body and is operable to rotate around the body independently of the movement of the other portions of the body. The rotating shell has a length that corresponds to the distance between the first lip and the second lip.

A milking cup comprising a body having a top portion and a bottom portion. The top portion has a first lip formed thereon and the bottom portion has a second lip formed thereon. The first lip and the second lip are separated by a distance. The milking cup further comprises a rotating shell positioned between and secured by the first lip and the second lip, wherein the rotating shell encircles the body and is operable to rotate around the body independently of the movement of the other portions of the body. The rotating shell has a length that corresponds to the distance between the first lip and the second lip.

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.