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 milking robot for automated milking of milking animals, comprising a cylinder supporting movement of at least one movable component. The cylinder has a wall with a ventilation opening and a cylinder rod which can move in and out of the cylinder. The cylinder wall surrounds at least one variable volume part for movement of the cylinder rod. The opening configures the cylinder to remain in virtual pressure equilibrium with an environment. A gas capture device is connected which has a variable volume and which together with the variable volume part, forms an air-tight gas volume. Thus the variable volume part is kept at almost ambient pressure, so that no unnecessary counter-pressure occurs in the cylinder, during extension and retraction of the cylinder rod. Also less to no exchange of gas and dirt with the environment can take place for longer life and better reliability of the cylinder.

A milking robot for automated milking of milking animals, comprising a cylinder supporting movement of at least one movable component. The cylinder has a wall with a ventilation opening and a cylinder rod which can move in and out of the cylinder. The cylinder wall surrounds at least one variable volume part for movement of the cylinder rod. The opening configures the cylinder to remain in virtual pressure equilibrium with an environment. A gas capture device is connected which has a variable volume and which together with the variable volume part, forms an air-tight gas volume. Thus the variable volume part is kept at almost ambient pressure, so that no unnecessary counter-pressure occurs in the cylinder, during extension and retraction of the cylinder rod. Also less to no exchange of gas and dirt with the environment can take place for longer life and better reliability of the cylinder.

A vacuum pump arrangement for a milking plant includes a main vacuum conduit with at least two vacuum pump units for maintaining a system vacuum in the main vacuum conduit. Each of the vacuum pump units includes a pump, a vacuum tank connected to the pump by an intermediate conduit, and an inlet conduit connecting the vacuum tank to the main vacuum conduit. A drainage extends from the vacuum tank and includes a draining valve. The pump sucks air from the main vacuum conduit via the inlet conduit, the vacuum tank and the intermediate conduit. The vacuum pump unit includes a closing valve provided on the inlet conduit and configured to close the inlet conduit in an automatic manner when the pump has been stopped.

A differential vacuum system for use with a milking system. The differential vacuum system is configured to modulate the fluid pressure in the pulsation volume to cause a milking operation on a teat of an animal that is inserted into the bore of a liner. The pulsation cycle includes an “on” phase to open the liner and thereby enable milk flow from the teat, and an “off” phase in which the pulsation volume is at an increased pressure relative to the “on” phase to close the liner bore to thereby stop milk flow from the teat. The differential vacuum system controls the maximum vacuum applied to the pulsation volume to exceed the maximum vacuum applied to the liner bore.

A milking device (10) has a teat cup (1) with liner (3) and milk claw (30). The liner includes a bore part (3b) elastically deformable between an open and closed state arranged inside a shell (2) to form space between an inner surface of the shell and the bore part; a mouthpiece part 3a disposed at one end of the bore part and closes one end part of the shell and into which a teat is inserted; and a short milk tube part (3d) disposed at the other end side of the bore part and closes the other end part of the shell and through which milk from the teat at the bore part flows. A short milk tube part (3d) is coupled to the claw. Vents (3aa, 3da, 36) are provided to a plurality of places on the mouthpiece part, the short milk tube part, and the claw.

An automatic milking machine extracts milk from the teats of an animal by applying a milking vacuum to a respective teat receiving cavity of a teat cup (111, 112, 113, 114) each in which one of the teats is located during a milking session. The milking session includes a boost phase (TBOOST) and is concluded by an exit phase (TEXIT). During the boost phase (TBOOST), the milking vacuum is applied at an elevated pressure level. During the exit phase, the milking vacuum is applied at one or more levels, each of which is lower than the elevated pressure level. The operation of the automatic milking machine transitions from the boost phase (TBOOST) to the exit phase (TEXIT) when (t2) a temporal criterion is fulfilled.

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 control valve and a membrane for a moving a valve disk of a control valve between a first position and a second position are provided. The membrane has a central axis perpendicular to an extension plane of the membrane. The membrane includes an outer annular rim portion, a central portion configured to be connected the valve disk, and a flexible portion that is annular and provided between the central portion and the outer annular rim portion. The membrane is flexible to permit the central portion to move back and forth along the central axis, thereby permitting the valve disk to move to one of the first position and the second position. The membrane is designed with an inherent pre-tensioning of the flexible portion, which permits the membrane to exert a force on the valve disk from the first position towards the second position.