A system of solar thermal collectors and an HVAC controller draw heated air through a solar thermal absorbing needle-punched propylene geotextile with limited permeability to air flow, into the interior of poultry livestock house. In various embodiments, the poultry livestock house is divided into zones. Groups of collectors are joined with breather holes on opposite sides of the collectors and solid sides on the ends of each group. Groups of collectors serve each zone of the poultry livestock house. In an embodiment of the system the Environmental Optimization System (“EOS”) provides a system for the intelligent control and monitoring the broiler poultry livestock structure environment through the utilization of a variety of environmental and livestock behavior sensors, apparatus for controlling the thermal collection and existing interior heating/air conditioning/ventilation (“HVAC”) systems, and Internet or cloud based intelligent control and monitoring capabilities of the system. In various embodiments central sensor data aggregation is utilized to provide improved optimization control for livestock zones within individual structures based on data from multiple structures.

A system of solar thermal collectors and an HVAC controller draw heated air through a solar thermal absorbing needle-punched propylene geotextile with limited permeability to air flow, into the interior of poultry livestock house. In various embodiments, the poultry livestock house is divided into zones. Groups of collectors are joined with breather holes on opposite sides of the collectors and solid sides on the ends of each group. Groups of collectors serve each zone of the poultry livestock house. In an embodiment of the system the Environmental Optimization System (“EOS”) provides a system for the intelligent control and monitoring the broiler poultry livestock structure environment through the utilization of a variety of environmental and livestock behavior sensors, apparatus for controlling the thermal collection and existing interior heating/air conditioning/ventilation (“HVAC”) systems, and Internet or cloud based intelligent control and monitoring capabilities of the system. In various embodiments central sensor data aggregation is utilized to provide improved optimization control for livestock zones within individual structures based on data from multiple structures.

A low profile brooder is provided, comprising a venturi, a burner base, a burner cap, and a baffle. The burner base and the burner cap reside adjacent to each other, with the burner cap disposed above the burner base and with a distribution chamber between them. A central axis is defined. A venturi resides below the burner base and is in fluid communication with the distribution chamber at the central axis. The venturi defines a fuel flow path between its upstream and downstream ends. The fuel flow path resides at least partially at one or more of an acute angle, a perpendicular angle, and an obtuse angle to the central axis. A baffle resides in the distribution chamber between the central axis and the periphery.

A low profile brooder is provided, comprising a venturi, a burner base, a burner cap, and a baffle. The burner base and the burner cap reside adjacent to each other, with the burner cap disposed above the burner base and with a distribution chamber between them. A central axis is defined. A venturi resides below the burner base and is in fluid communication with the distribution chamber at the central axis. The venturi defines a fuel flow path between its upstream and downstream ends. The fuel flow path resides at least partially at one or more of an acute angle, a perpendicular angle, and an obtuse angle to the central axis. A baffle resides in the distribution chamber between the central axis and the periphery.

A premixed underground ventilated henhouse includes a gable, a sidewall, a roof and a floor. An inner chamber is further provided in the middle of the henhouse. A partition is hermetically provided between the sidewall and an inner wall. An air inlet plate is provided between the two inner walls. A plurality of fans and a plurality of air inlet windows are uniformly provided on an inner roof. A plurality of wet curtains and an air vent are provided on the sidewall. Air outlet slots are uniformly provided on the inner wall. An underground exhaust bunker is provided under the floor. A vent pipe and a fan are provided on one side of the underground exhaust bunker. An air outlet is provided at an upper end of the vent pipe.

A premixed underground ventilated henhouse includes a gable, a sidewall, a roof and a floor. An inner chamber is further provided in the middle of the henhouse. A partition is hermetically provided between the sidewall and an inner wall. An air inlet plate is provided between the two inner walls. A plurality of fans and a plurality of air inlet windows are uniformly provided on an inner roof. A plurality of wet curtains and an air vent are provided on the sidewall. Air outlet slots are uniformly provided on the inner wall. An underground exhaust bunker is provided under the floor. A vent pipe and a fan are provided on one side of the underground exhaust bunker. An air outlet is provided at an upper end of the vent pipe.

A draw-ramp egg-teeter-totter wild-animal-shield chicken coop, comprising: a first and a second and a third and a fourth roosting walls attached to one another, a roosting roof attached to the first and the second and the third and the fourth roosting wall, a passage opening formed in the fourth roosting wall, a first nesting wall attached to the third roosting wall along the opposite passage-opening edges, a second nesting wall attached to the first nesting wall, a third nesting wall attached to the second nesting wall, a slanted nesting floor attached to the first nesting wall and the third nesting wall, a teeter-totter axle attached to the slanted nesting floor, an automatic egg-collecting teeter-totter seesawingly attached to the teeter-totter axle, an automatic egg-laying indicator attached to one of the two opposite teeter-totter ends, a teeter-totter-angle-adjusting screw threadedly attached to another one of the two opposite teeter-totter ends, a draw-ramp opening formed in the first roosting wall, two rails respectively attached to the first roosting wall along the top and the bottom of the draw-ramp opening edges, a sliding door slidably attached to and between the two rails, a door rod attached to the sliding door, a door-rod handle attached to the door rod, an automatic spring-loaded handle hook seesawingly attached to the door-rod handle, a handle-hook ring attached to the second roosting wall, a plurality of wall panels respectively attached to one another or the first roosting wall or the second roosting wall or the third roosting wall or the fourth roosting wall, a door panel hinged to one of the wall panels, a latch-tip brace attached to one of the wall panels, a latch-body brace attached to the door panel, a C-shaped cut-out formed in the latch-body brace, a latch pivotably and slidably attached to the latch-body brace, a latch lever molded to the latch, a spring housing molded to the latch-body brace, an automatic-relatching twistable compressable spring attached to the latch at one of the two opposite spring ends and attached to the spring housing at another one of the two opposite spring ends, a wire-strengthening anti-pushing vertical shield positioned on the inside of the chicken coop against the wall panels and the door panel, a panel-strengthening anti-growing anti-digging horizontal shield molded to the wire-strengthening anti-pushing vertical shield and positioned under the wall panels or the door panel, a plurality of wire-panel-coupling hooks respectively molded on or formed on the wire-strengthening anti-pushing vertical shield, a plurality of panel-raising anti-rotting ridges respectively molded on or formed on the wire-stren

A livestock central air conditioner and a livestock house, relates to the art field of livestock house and equipment. The livestock central air conditioner including a heat exchange unit 1, a cooling component 2, an axial fan 3 and an air duct 4; the livestock house including a house 6 and the livestock central air conditioner; a ventilation fan 63 is provided at the location of the exhaust outlet 62 on the house 6.

A method of rearing chickens comprises providing a chicken shed (10) having a floor area (12) over which the chickens can move freely. The shed (10) is provided with a plurality of lights (18) arranged to illuminate respective different regions of the floor area (12) so that, collectively, the lights (18) are able to illuminate substantially all of the floor area (12). The shed (10) is provided a plurality of cameras (20) arranged to view respective different regions of the floor area (12) so that, collectively, the cameras (20) are able to view substantially all of the floor area (12). Chickens are provided in the livestock shed (10) on the floor area (12). A controller (22) is provided and is operatively connected to the lights (18) and to the cameras (20). The controller (22) receives and analyses signals, such as images, from the cameras (20). The controller (22) controls the lights (18) to adjust illumination provided to the floor area (12) by the controlled lights (18) in a manner dependent on the signals from the cameras (20). The controller (22) is able to control each light (18) independently of the other lights (18). In some situations, the control of the lights (18) causes a predetermined desired response in the chickens. In some cases, the predetermined desired response overcomes or circumvents an undesirable situation recognised by the controller from analysis of the signals from the cameras (20).

A method of rearing chickens comprises providing a chicken shed (10) having a floor area (12) over which the chickens can move freely. The shed (10) is provided with a plurality of lights (18) arranged to illuminate respective different regions of the floor area (12) so that, collectively, the lights (18) are able to illuminate substantially all of the floor area (12). The shed (10) is provided a plurality of cameras (20) arranged to view respective different regions of the floor area (12) so that, collectively, the cameras (20) are able to view substantially all of the floor area (12). Chickens are provided in the livestock shed (10) on the floor area (12). A controller (22) is provided and is operatively connected to the lights (18) and to the cameras (20). The controller (22) receives and analyses signals, such as images, from the cameras (20). The controller (22) controls the lights (18) to adjust illumination provided to the floor area (12) by the controlled lights (18) in a manner dependent on the signals from the cameras (20). The controller (22) is able to control each light (18) independently of the other lights (18). In some situations, the control of the lights (18) causes a predetermined desired response in the chickens. In some cases, the predetermined desired response overcomes or circumvents an undesirable situation recognised by the controller from analysis of the signals from the cameras (20).