A valve apparatus comprises a housing, a solenoid operable to receive electrical current flow, and an enclosure, the enclosure housing the solenoid, a magnet coupled to the enclosure, a plunger comprising a stopper and a conductive portion, and a spring coupled to the plunger. When the solenoid receives a first current, the solenoid applies a first magnetic force onto the plunger causing the stopper to disengage from the housing outlet, the conductive portion of the plunger magnetically connects with the magnet, and the stopper remains disengaged from the housing outlet after the first period of time expires. When the conductive portion is magnetically connected to the magnet and the solenoid receives a second current, the solenoid applies a second magnetic force onto the plunger causing the conductive portion of the plunger to disconnect from the magnet so that the stopper engages with the housing outlet.

A fluid measurement device and methods of manufacturing and using the same are disclosed. The fluid measurement device includes a conduit configured to transport a fluid, a conductivity sensor in the conduit, and a voltage sensor in the conduit and having first and second rings, probes, or plates. The conductivity sensor is configured to determine the conductivity of the fluid. The voltage sensor is configured to receive a first voltage on the first ring, probe, or plate and detect a capacitance or a second voltage on the second ring, probe, or plate. A value of the capacitance or second voltage corresponds to the amount of fluid in the voltage sensor. The total amount of fluid through the conduit may be determined from amount of fluid in the voltage sensor, the fluid flow rate, the fluid velocity, and the number of samples or the sampling rate.

A milking system includes one or more milking devices and a control unit. The system is provided with a plurality of milking cups, a first milk jar for receiving the milking, a first pumping device for pumping the milking, a second milk jar for receiving the milking from the first milk jar, a second pumping device for pumping at least a part of the milking, and at least one storage tank for storing at least a part of the milking. The second pumping device pumps the milking at a lower flow rate than that at which the first pumping device pumps the milking. As a result, the milk is for the most part moved with low mechanical load and little admixture with air which improves milk quality. In the case of a plurality of milking devices in the milking system, various milkings can be moved and treated separately.

A milking system includes one or more milking devices and a control unit. The system is provided with a plurality of milking cups, a first milk jar for receiving the milking, a first pumping device for pumping the milking, a second milk jar for receiving the milking from the first milk jar, a second pumping device for pumping at least a part of the milking, and at least one storage tank for storing at least a part of the milking. The second pumping device pumps the milking at a lower flow rate than that at which the first pumping device pumps the milking. As a result, the milk is for the most part moved with low mechanical load and little admixture with air which improves milk quality. In the case of a plurality of milking devices in the milking system, various milkings can be moved and treated separately.

A milk conduit, that connects to a teatcup to be attached to a teat of an animal to be milked, includes a first end portion defining a first end and configured to be connected to the teatcup, a second end portion defining a second end, and a conduit portion located between the first end portion and the second end portion. The milk conduit defines a milk channel extending through the first end portion, the conduit portion and the second end portion. The first end portion is received in an opening extending through a bottom wall of the teatcup. The first end portion includes a first circumferential groove configured that engages in the bottom wall of the teatcup.

A space divider (4) of a milking parlor arrangement for at least one milking parlor (3) for milking milk-producing animals (T), wherein the space divider (4) is arranged approximately parallel to a longitudinal axis of the animal (T) to be milked, has an arm device (6) having a milking cluster (5, 5′), which can be adjusted from a parking position to a working position and back. The arm device (6) is arranged with the milking cluster (5) in the parking position in the space divider (4), wherein the milking cluster (5, 5′) can be adjusted into the working position laterally to the animal (T) to be milked between the front and rear legs thereof. The milking cluster (5, 5′) comprises two halves, wherein each half has a specific set of at least one teatcup (5a). The space divider (4) is designed in such a way that no additional space is required between adjacent animals (T), so that many animals (T) can be milked in a milking parlor arrangement (1, 1′, 1″) while the smallest possible amount of space is required. A milking parlor arrangement (1, 1′, 1″) has at least one external robot (12).

A milking device for milking a dairy animal comprises a teat cup with a cup wall and a teat liner and a pulsation space situated in between, to which pulsation space a pulsation device is connected which is configured to apply a pressure that varies in pulsations to the pulsation space in order to open and close the teat liner, and which pulsation device comprises a supply line which is controllable by a first operable valve, in particular closable, for supplying a first pressure, a supply line which is controllable by a second operable valve, in particular closable, for supplying a second pressure, which is a lower pressure than the first pressure, and a control unit which is configured to generate control signals for operating the first valve and the second valve, wherein the first valve, and preferably also the second valve, is a controllable valve having a passage which is adjustable by means of the control signals, wherein the passage of the first valve, and preferably of the second valve, respectively, is adjustable during at least one pulsation phase by the control unit via the control signals.

The present invention therefore provides a modular system for constraining milk flow in a pressure-dependent and/or controlled manner. Due to the modular concept, the required properties of the device can be adjusted in an efficient manner. For example, it is possible to adapt the connection to a milk line, i.e., the geometry of the connection arrangement, specifically to the existing conditions of the milking stall and the milking system. The pressure-dependent constraining when milking can be adjusted specifically for a single teat or in pairs for two teats by using a respective module component. If necessary, adjustment of the range for reliable switching can be performed by selecting suitable spring components and/or by adapting the flow resistance. The flow resistance is adjustable by using a suitable connection arrangement and/or by exchanging a modular flow body.

A safety valve arrangement and method, having an upstream block valve, a downstream block valve, and a pressure monitored galley between the upstream valve and the downstream valve.

A milking device for milking a dairy animal includes a teat cup with a cup wall and a teat liner and a pulsation space situated in between, the pulsation space being connected to a pulsation device that is configured to apply a pressure that varies in pulsations to the pulsation space in order to open and close the teat liner. The pulsation device includes a supply line controllable by a first operable valve for supplying a first pressure, a supply line controllable by a second operable valve for supplying a second pressure lower than the first pressure, and a control unit configured to generate control signals for operating the first and second valves. At least the first valve is a controllable valve having a passage that is adjustable during at least one pulsation phase by the control unit.