The disclosure concerns a milking installation including milking positions configured to milk one animal at a time, a first common milk line connected to a first milk receiver, a second common milk line connected to a second milk receiver, a control arrangement, and at least one robot arm. Each milking position includes at least one teat cup and a flow directing arrangement, the flow directing arrangement including an inlet arrangement connected to the teat cup, a first outlet arrangement connected to the first milk line, and a second outlet arrangement connected to the second milk line. The control arrangement is configured to control the flow directing arrangement to fluidly connect the teat cup via the inlet arrangement with either the first outlet arrangement or the second outlet arrangement.

A connector and a teatcup that includes a connector and a cartridge. The cartridge includes a sleeve, having a first end and a second end, and a teatcup liner mounted in the sleeve and having an inner space for receiving a teat. The connector is configured to connect a milk conduit to the cartridge. The connector includes a casing, which defines a longitudinal center axis (x) and encloses a connection space. The casing has an inner surface facing the connection space. The casing includes an inlet opening for the cartridge to the connection space, and an outlet opening for the milk conduit. Locking parts are provided on the inner surface of the casing and configured to permit locking of the cartridge in the connector.

A milking system includes a milking device, and a milk storage system having: a temporary milk storage vessel for temporarily storing milk from a plurality of milking operations, a milk pipe from the milking device to the temporary milk storage vessel, a milk tank for storing the milk from the temporary milk storage vessel, a control unit, a main milk pipe from the temporary milk storage vessel to the milk tank, a pressurized liquid supply which is controllable by the control unit and is provided and configured to supply a pressurized liquid, other than milk, to the milk storage system, a first and a second discharge provided on the main milk pipe, a selection device which is controllable by the control unit and is on the main milk pipe towards the first discharge or the second discharge, wherein the control unit is configured to perform a milk transferring action for transferring milk in the main milk pipe into the milk tank with the aid of the pressurized liquid, wherein the liquid transferring action includes bringing the pressurized liquid supply and the first discharge into liquid connection with the main milk pipe, and breaking a liquid connection of the main milk pipe with the second discharge, allowing an amount of pressurized liquid to flow under pressure from the pressurized liquid supply into the main milk pipe, and breaking the liquid connection between the main milk pipe and the first discharge. Transferring the milk in this way means that it is subjected to less mechanical load and mixed with less air, which benefits the quality. The invention also provides a temporary milk storage vessel and method of this type.

A milk tank system includes a first holder configured for intermediate storage of milk from several milkings of a milking device, and not being a milk glass; a second holder for storage of milk from the first holder; a transport device for transporting milk including a milk line from the first holder to the second holder, via which milk line the second holder may be brought into fluidic connection with the first holder, and a shut-off for shutting off the fluidic connection, in particular from the first holder to the milk line, wherein the transport device has a first operating state which is configured for collecting milk in the first holder, and a second operating state which is configured for transferring the milk from the first holder to the second holder, wherein the milk tank system further includes a control system for switching the transport device from the first to the second operating state when the milk in the first holder reaches a switching milk level which changes over time. Because the pumping of the milk from the intermediate milk storage vessel does not always begin at the same or comparable maximum milk level, but preferably at an ever increasing level, potentially caking milk residue is always rinsed away on a subsequent filling.

A milking system including: at least one milking device; a milk storage vessel storing milk obtained with the milking device; a milk line system with a milk line with a first end connected to the milking device and with a second end connected to the milk storage vessel; and a monitoring system including: a sensor configured to measure a fluid parameter value of a fluid in the milk line, and a control system actively connected to the sensor and configured to process the measured fluid parameter value and generate a transition signal on fulfilment of a predefined transition criterion. The milk line includes a substantially vertical line portion, and a proposed discharge direction of milk runs through the milk line from the milking device to the milk storage vessel and is raised through the line portion, wherein the sensor is placed in or on the substantially vertical line portion.

The invention relates to a conduit for transferring milk. The conduit is provided with at least one flexible wall, which divides the conduit into at least one milk duct and at least one secondary duct. The milk duct and the at least one secondary duct extend along a longitudinal axis of the conduit, it being possible for the at least one milk duct to be substantially emptied by pressing through filling the at least one secondary duct.

A milking system includes several milking devices, each having a milk-carrying part, a temporary milk storage vessel, a milk pipe system, a milk storage tank, and a main milk pipe, which connects the temporary milk storage vessel to the milk storage tank. The milking system includes a first cleaning device having at least one first cleaning liquid supply and at least a pump, which cleaning device is configured to clean at least the milk-carrying part of at least one milking device and a part of the milk pipe system which connects the milk-carrying part to the temporary milk storage vessel, by transferring cleaning liquid from the cleaning liquid supply through at least the milk-carrying part of the at least one milking device and through said part of the milk pipe system to the temporary milk storage vessel by pumping. The temporary milk storage vessel includes a main pump for transferring liquid from the temporary milk storage vessel through the main milk pipe in the direction of the milk storage tank. The milking system includes a second, additional cleaning device with at least one second, additional cleaning liquid supply, which second cleaning device is configured to supply additional cleaning liquid from the second cleaning liquid supply in a direction of flow from the temporary milk storage vessel towards the main milk pipe. The second cleaning liquid supply is situated downstream of at least each of the milking devices, viewed in said direction of flow.

A milking device for milking dairy cattle contains at least one teat cup which is connected to a milk-collecting container by a hose. In order to simplify the production of the milking device, at least one surface coming in contact with the milk or one component of the teat cup and/or of the milk-collecting container is made of an alloy that contains at least 50% Cu and, as a further alloying constituent, at least 2% Zn or at least 2% Sn.

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.

A milking arrangement with a plurality of milk stations connected to the milk transport line, a receiver connected to the transport line that receives milk transported from the milk stations via the transport line, and a vacuum system that supplies a vacuum in the transport line via the receiver, with a cleaning liquid source connected to the transport line, a controllable injector that introduces an amount of gas into the transport line to produce a temporary pressure increase therein that causes a slug of a cleaning liquid from the cleaning liquid source to be formed and forwarded through the transport line, and a control system configured to control the operation of the injector, wherein the control system is configured to control characteristics of the slug by controlling the vacuum level supplied by the vacuum system and/or the amount of gas introduced via the controllable injector.