A vacuum controller for isolating the vacuum chamber of a vacuum pump, the vacuum controller comprising a shell comprising an inlet and an outlet, the outlet being fluidly connected to the vacuum pump, a diaphragm disposed within the shell and defining a first cavity and a second cavity within the shell, the first and second cavities being on opposite sides of the diaphragm and the second cavity being in fluid communication with the outlet, a pressure balance module adapted to selectively fluidly connect the first and second cavities in an open configuration and a controller adapted to selectively actuate the pressure balance module wherein the diaphragm fluidly restricts at least one of the inlet and the outlet when the pressure balance module is in a closed configuration.

A vacuum controller for isolating the vacuum chamber of a vacuum pump, the vacuum controller comprising a shell comprising an inlet and an outlet, the outlet being fluidly connected to the vacuum pump, a diaphragm disposed within the shell and defining a first cavity and a second cavity within the shell, the first and second cavities being on opposite sides of the diaphragm and the second cavity being in fluid communication with the outlet, a pressure balance module adapted to selectively fluidly connect the first and second cavities in an open configuration and a controller adapted to selectively actuate the pressure balance module wherein the diaphragm fluidly restricts at least one of the inlet and the outlet when the pressure balance module is in a closed configuration.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a board coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The board is able to pivot from a down position to an up position and has an aperture through which the imaging device can pass through when the board lowers from the up position to the down position. The processor is coupled to both the imaging device and the board and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the board from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a board coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The board is able to pivot from a down position to an up position and has an aperture through which the imaging device can pass through when the board lowers from the up position to the down position. The processor is coupled to both the imaging device and the board and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the board from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A diagnostic apparatus for testing a milking point of a milking machine includes sensors for measuring fluid-transport related parameters, including various pressure levels and/or flow values relating to a set of teatcups includes a controllable valve and a set of test tubes. Each test tube is configured to be attached to one teatcup, where the controllable valve selectively arranges a particular one of the test tubes for measurement of at least one parameter via one of the sensors in response to a control signal. The measurements are performed while all the teatcups are simultaneously attached to the test tubes and an external vacuum pressure is applied either on a milk-line side of the controllable valve or on a side opposite to the milk-line side relative to the controllable valve.

A diagnostic apparatus for testing a milking point of a milking machine includes sensors for measuring fluid-transport related parameters, including various pressure levels and/or flow values relating to a set of teatcups includes a controllable valve and a set of test tubes. Each test tube is configured to be attached to one teatcup, where the controllable valve selectively arranges a particular one of the test tubes for measurement of at least one parameter via one of the sensors in response to a control signal. The measurements are performed while all the teatcups are simultaneously attached to the test tubes and an external vacuum pressure is applied either on a milk-line side of the controllable valve or on a side opposite to the milk-line side relative to the controllable valve.

A system for cleaning a dairy animal milker unit and applying dip to a dairy animal, the system includes a main control, an air supply, a water supply, a backflush fluid supply, a dip supply, a stall control for receiving the air, water, backflush fluid and dip supplies, and a safety valve that is adjacent to a downstream portion of the milker unit to control backflush and dip fluids being fed to the milker unit.

A system for cleaning a dairy animal milker unit and applying dip to a dairy animal, the system includes a main control, an air supply, a water supply, a backflush fluid supply, a dip supply, a stall control for receiving the air, water, backflush fluid and dip supplies, and a safety valve that is adjacent to a downstream portion of the milker unit to control backflush and dip fluids being fed to the milker unit.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.