A device for sequentially dispensing individual objects includes a housing having a first housing portion which is conically-shaped. The first housing portion has a first end proximate a supply of objects and a second end proximate a location where the objects are to be dispensed. There is a spiral race, disposed on an interior surface of the first housing portion and extending from the first end to the second end of the first housing portion, along which the objects to be dispensed travel.

The present invention discloses, inter alia, a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); a plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The invention also discloses a method of positioning at least one of a plurality of mobile units in an FDR comprising steps of providing a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); and the plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The present invention further discloses a dairy farm characterized by (a) an array of n stalls side-by-side along an X axis on the dairy animal's level. Each of the stalls is configured by means of size and shape to accommodate a dairy animal, having a main axis Y that is substantially perpendicular to axis X, a front side and an opposite rear side; and (b) a common elevated road surface provided on a higher level, above the stalls. This upper road surface extends along the X axis and is constructed to allow free passage of mobile units, including mobile longitudinal milking units, in a direction along the X axis, along the Y axis, a rotation about the X axis, a rotation about the Y axis, a rotation about the Z axis, and any combination thereof. The present invention further discloses means and method that in a stall, a gate located between the animal and the feeding line is thereby configured to at least temporarily prevent or otherwise limit free access of said animal to its feed.

The present invention discloses, inter alia, a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); a plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The invention also discloses a method of positioning at least one of a plurality of mobile units in an FDR comprising steps of providing a free dome range system (FDR) comprising at least one front elevated rail (FER); at least one rear elevated rail (RER); and the plurality of mobile units, each of the plurality of mobile units movable along a member of a group consisting of: the at least one FER, the least one RER and any combination thereof. The present invention further discloses a dairy farm characterized by (a) an array of n stalls side-by-side along an X axis on the dairy animal's level. Each of the stalls is configured by means of size and shape to accommodate a dairy animal, having a main axis Y that is substantially perpendicular to axis X, a front side and an opposite rear side; and (b) a common elevated road surface provided on a higher level, above the stalls. This upper road surface extends along the X axis and is constructed to allow free passage of mobile units, including mobile longitudinal milking units, in a direction along the X axis, along the Y axis, a rotation about the X axis, a rotation about the Y axis, a rotation about the Z axis, and any combination thereof. The present invention further discloses means and method that in a stall, a gate located between the animal and the feeding line is thereby configured to at least temporarily prevent or otherwise limit free access of said animal to its feed.

The present invention relates to a control unit (116) for a game or fish feeder (100). The control unit (116) is mounted on the feeder (100) and comprises: means (130) for controlling the powering of a drive unit (110) of said feeder (100) for controlled output of feed from the feeder (100); a wireless transmitter (138) arranged to communicate over a wireless network (146) with a remote unit (140); a sensor (132; 134) for measuring a parameter of the feeder (100); and means (124) for determining whether a measured parameter value provided by said sensor (132; 134) fulfills a predetermined condition in order to detect an action-requiring state of the feeder (100). In response to a detected action-requiring state, the wireless transmitter (138) is triggered to send a notification to said remote unit (140).

The present invention relates to a control unit (116) for a game or fish feeder (100). The control unit (116) is mounted on the feeder (100) and comprises: means (130) for controlling the powering of a drive unit (110) of said feeder (100) for controlled output of feed from the feeder (100); a wireless transmitter (138) arranged to communicate over a wireless network (146) with a remote unit (140); a sensor (132; 134) for measuring a parameter of the feeder (100); and means (124) for determining whether a measured parameter value provided by said sensor (132; 134) fulfills a predetermined condition in order to detect an action-requiring state of the feeder (100). In response to a detected action-requiring state, the wireless transmitter (138) is triggered to send a notification to said remote unit (140).

Systems and methods provide automated data collection of feed behavior and intake for animals in confinement where the animal ingests feed from a feed station that includes a first and second feed container each of which holds a feed that is freely accessible to the animal, and a respective first and second weight sensor each of which senses a change in weight of the respective feed in the container. A processor is configured to transmit instructions to cause it to receive from the weight sensors, a plurality signals indicative of a change in weight in the first and second feed containers. The processor records a reduction in weight sensed by the first or the second sensor as consumption of the respective feed, and records a change in weight sensed by the first or the second sensor as feeding activity at the respective feed container.

The present invention relates to a system and method for monitoring in real time the nutriment intake (feed and/or water) of farm animals, including but not limited to poultry, turkeys, pigs and cows, based on the measurement and identification of the nutriment uptake sounds and/or the working of the nutriment supply system, while the presence and eating position of the animals is monitored by using real-time image analysis.

The present invention relates to a system and method for monitoring in real time the nutriment intake (feed and/or water) of farm animals, including but not limited to poultry, turkeys, pigs and cows, based on the measurement and identification of the nutriment uptake sounds and/or the working of the nutriment supply system, while the presence and eating position of the animals is monitored by using real-time image analysis.

A scale controller system and method of using the system is disclosed. The scale controller is adapted for use with a grain cart or similar implement that includes a discharge opening and conveyor. The system includes a scale and a plurality of sensors that work together to automate numerous functions that are typically performed manually. For example, the present invention discloses a system that automatically records the amount of material loaded or unloaded by continuously monitoring the load on a scale and the RPMs of a power take-off shaft that drives a conveyor.

A scale controller system and method of using the system is disclosed. The scale controller is adapted for use with a grain cart or similar implement that includes a discharge opening and conveyor. The system includes a scale and a plurality of sensors that work together to automate numerous functions that are typically performed manually. For example, the present invention discloses a system that automatically records the amount of material loaded or unloaded by continuously monitoring the load on a scale and the RPMs of a power take-off shaft that drives a conveyor.