The disclosed technology includes systems and methods for continuously supplying livestock to a processing plant. The disclosed technology can include an enclosure configured to house livestock. The enclosure can include an enclosure entrance, an enclosure exit, and moveable walls to partition the enclosure into separate pens and automatically direct the livestock from the enclosure entrance toward the enclosure exit. A passageway can be connected to the enclosure exit and include moveable walls to automatically direct the livestock from the enclosure exit toward a processing plant. The moveable walls can be configured to move at a predetermined speed such that the plurality of livestock enter the enclosure as offspring, are reared in the enclosure, and are directed through the enclosure exit into the passageway approximately when the plurality of livestock have reached slaughter weight.

The disclosed technology includes systems and methods for continuously supplying livestock to a processing plant. The disclosed technology can include an enclosure configured to house livestock. The enclosure can include an enclosure entrance, an enclosure exit, and moveable walls to partition the enclosure into separate pens and automatically direct the livestock from the enclosure entrance toward the enclosure exit. A passageway can be connected to the enclosure exit and include moveable walls to automatically direct the livestock from the enclosure exit toward a processing plant. The moveable walls can be configured to move at a predetermined speed such that the plurality of livestock enter the enclosure as offspring, are reared in the enclosure, and are directed through the enclosure exit into the passageway approximately when the plurality of livestock have reached slaughter weight.

The disclosed technology includes systems and methods for continuously supplying livestock to a processing plant. The disclosed technology can include an enclosure configured to house livestock. The enclosure can include an enclosure entrance, an enclosure exit, and moveable walls to partition the enclosure into separate pens and automatically direct the livestock from the enclosure entrance toward the enclosure exit. A passageway can be connected to the enclosure exit and include moveable walls to automatically direct the livestock from the enclosure exit toward a processing plant. The moveable walls can be configured to move at a predetermined speed such that the plurality of livestock enter the enclosure as offspring, are reared in the enclosure, and are directed through the enclosure exit into the passageway approximately when the plurality of livestock have reached slaughter weight.

The disclosed technology includes systems and methods for continuously supplying livestock to a processing plant. The disclosed technology can include an enclosure configured to house livestock. The enclosure can include an enclosure entrance, an enclosure exit, and moveable walls to partition the enclosure into separate pens and automatically direct the livestock from the enclosure entrance toward the enclosure exit. A passageway can be connected to the enclosure exit and include moveable walls to automatically direct the livestock from the enclosure exit toward a processing plant. The moveable walls can be configured to move at a predetermined speed such that the plurality of livestock enter the enclosure as offspring, are reared in the enclosure, and are directed through the enclosure exit into the passageway approximately when the plurality of livestock have reached slaughter weight.

Disclosed is a pet cage, including a cage body having a cage opening and a door body for covering the cage opening. The cage body is provided with a rotating shaft at one end of the cage opening and a hanging bar at the other end of the cage opening, the hanging bar and the rotating shaft are oppositely disposed. The door body is provided with a rotation portion on one side and a hook portion on the other side, the rotation portion includes a rotation groove, the hook portion includes a hook groove opposite to the rotation groove. The rotating shaft is configured to be sheathed inside the rotation groove so that the rotation portion is rotatably connected to the rotating shaft, and the hook portion is hooked to the hanging bar. The depth of the rotation groove is greater than the depth of the hook groove.

This invention relates to laying nest having a rack drive expulsion system. As disclosed herein, the invention preferably comprises a laying nest for hens comprising a box and a rack drive floor expulsion system. The floor pivotably moves between first and second positions by virtue of a gear rack that is fixedly connected to and disposed within the box, and a gear wheel that is rotatably connected to the floor. Accordingly, the expulsion system provides for the selected removal of hens from the laying nests as desired.

This invention relates to laying nest having a rack drive expulsion system. As disclosed herein, the invention preferably comprises a laying nest for hens comprising a box and a rack drive floor expulsion system. The floor pivotably moves between first and second positions by virtue of a gear rack that is fixedly connected to and disposed within the box, and a gear wheel that is rotatably connected to the floor. Accordingly, the expulsion system provides for the selected removal of hens from the laying nests as desired.

Object release enclosures are disclosed. Methods of making and using object release enclosures are also disclosed.

A hydroponic growing system having multiple growing units, wherein each growing unit includes a container for a plant. The growing units are linked through a water recirculation system. The water recirculation system includes a sprayer located on an upper, inner portion of the growing unit above a water level. Water is sprayed downward onto the water surface and plants creating increased levels of oxygen for optimal growth. Each growing unit is connected to a water return channel that directs water to a water pump to circulate water throughout the system via a pressurized manifold system. Sprayers are connected to the manifold for introducing water into the growing unit. The system delivers limitless oxygen to roots and can produce healthy plants with fewer nutrients than conventional systems. The system provides increased oxygen levels such that plant life can thrive, even in less than optimal conditions.

The invention relates to a rack (10) for receiving fattening poultry cages, (20) comprising: a frame structure (12), a plurality of levels (14) for receiving a plurality of fattening poultry cages (20), and a plurality of conveying means (16) associated with each of the levels (14). The means of conveyance (16) are arranged in such a way that they transport the cages (20) located in the rack (10) within the respective level (14) to and/or away from a unloading point (30). Further, the invention relates to a fattening poultry cage (20) for arrangement in such a rack (10). Finally, the invention relates to a system of racks (10) and cages (20) according to the invention. The system may comprise an industrial truck (22) with lifting means for removing cages (20) from or feeding cages into the rack (10), the lifting means comprising a plurality of fork carriages (24) arranged vertically one above the other and movable in a vertical direction relative to one another.