An improved, self-balancing water distribution system uses siphon characteristics to maintain negative pressure within the water system and to enable distribution of water to one or more distribution points, such as drinker lines with drinker nipples, at a controlled pressure, for consumption by poultry. The system includes water conduit connected to and configured to distribute water from a water supply reservoir to the one or more distribution points. The water level of the water supply reservoir is used to control the water pressure within the system. A vacuum apparatus is connected to the water conduit to remove entrapped air within the system to help maintain negative pressure within the conduit and throughout the system.

An improved, self-balancing water distribution system uses siphon characteristics to maintain negative pressure within the water system and to enable distribution of water to one or more distribution points, such as drinker lines with drinker nipples, at a controlled pressure, for consumption by poultry. The system includes water conduit connected to and configured to distribute water from a water supply reservoir to the one or more distribution points. The water level of the water supply reservoir is used to control the water pressure within the system. A vacuum apparatus is connected to the water conduit to remove entrapped air within the system to help maintain negative pressure within the conduit and throughout the system.

A top-fill hummingbird feeder is provided having a nectar container with a liquid flow opening at a lower end and a removable cap at an upper end, a feeding basin positioned below the nectar container, and a sealing mechanism associated with the liquid flow opening and the feeding basin. The sealing mechanism includes a bottle seal assembly configured for removable coupling with a base of the feeding basin, and a float valve captured by said bottle seal assembly to prevent rotation thereof while allowing the float valve to move upwardly and downwardly with changing nectar levels in the feeding basin. The float valve includes a float having a frame with a buoyant member mounted thereon, the buoyant member being made of a closed-cell foam.

A top-fill hummingbird feeder is provided having a nectar container with a liquid flow opening at a lower end and a removable cap at an upper end, a feeding basin positioned below the nectar container, and a sealing mechanism associated with the liquid flow opening and the feeding basin. The sealing mechanism includes a bottle seal assembly configured for removable coupling with a base of the feeding basin, and a float valve captured by said bottle seal assembly to prevent rotation thereof while allowing the float valve to move upwardly and downwardly with changing nectar levels in the feeding basin. The float valve includes a float having a frame with a buoyant member mounted thereon, the buoyant member being made of a closed-cell foam.

According to certain aspects of the present disclosure, a brooder is provided. The brooder includes a heater assembly comprising a heater base. A trough is disposed on the heater base and is formed by an inner wall and an outer wall. A tube is rotatably supported by the inner wall. A dome is adjustably supported on the tube.

According to certain aspects of the present disclosure, a brooder is provided. The brooder includes a heater assembly comprising a heater base. A trough is disposed on the heater base and is formed by an inner wall and an outer wall. A tube is rotatably supported by the inner wall. A dome is adjustably supported on the tube.

A top-fill hummingbird feeder is provided having a nectar container with a liquid flow opening at a lower end and a removable cap at an upper end, a feeding basin positioned below the nectar container, and a sealing mechanism associated with the liquid flow opening and the feeding basin. The sealing mechanism includes a bottle seal assembly configured for removable coupling with a base of the feeding basin, and a float valve captured by said bottle seal assembly to prevent rotation thereof while allowing the float valve to move upwardly and downwardly with changing nectar levels in the feeding basin. The float valve includes a float having a frame with a buoyant member mounted thereon, the buoyant member being made of a closed-cell foam.

A top-fill hummingbird feeder is provided having a nectar container with a liquid flow opening at a lower end and a removable cap at an upper end, a feeding basin positioned below the nectar container, and a sealing mechanism associated with the liquid flow opening and the feeding basin. The sealing mechanism includes a bottle seal assembly configured for removable coupling with a base of the feeding basin, and a float valve captured by said bottle seal assembly to prevent rotation thereof while allowing the float valve to move upwardly and downwardly with changing nectar levels in the feeding basin. The float valve includes a float having a frame with a buoyant member mounted thereon, the buoyant member being made of a closed-cell foam.

An improved, self-balancing water distribution system uses siphon characteristics to maintain negative pressure within the water system and to enable distribution of water to one or more distribution points, such as drinker lines with drinker nipples, at a controlled pressure, for consumption by poultry. The system includes water conduit connected to and configured to distribute water from a water supply reservoir to the one or more distribution points. The water level of the water supply reservoir is used to control the water pressure within the system. A vacuum apparatus is connected to the water conduit to remove entrapped air within the system to help maintain negative pressure within the conduit and throughout the system.

An improved, self-balancing water distribution system uses siphon characteristics to maintain negative pressure within the water system and to enable distribution of water to one or more distribution points, such as drinker lines with drinker nipples, at a controlled pressure, for consumption by poultry. The system includes water conduit connected to and configured to distribute water from a water supply reservoir to the one or more distribution points. The water level of the water supply reservoir is used to control the water pressure within the system. A vacuum apparatus is connected to the water conduit to remove entrapped air within the system to help maintain negative pressure within the conduit and throughout the system.