A feeding device for honeybees is described that can be used when open feeding honeybees using a container. The container is filled with liquid syrup. The feeding device can be placed over the liquid syrup. The feeding device includes several feeding holes on the surface of the liquid syrup. The honeybees can land on top of the surface of the feeding device and can drink the liquid syrup by reaching through the feeding holes on the feeding device. The feeding device prevents the honeybees from drowning in the liquid syrup and provides a safe surface for multiple honeybees to land on while open feeding.

A feeding device for honeybees is described that can be used when open feeding honeybees using a container. The container is filled with liquid syrup. The feeding device can be placed over the liquid syrup. The feeding device includes several feeding holes on the surface of the liquid syrup. The honeybees can land on top of the surface of the feeding device and can drink the liquid syrup by reaching through the feeding holes on the feeding device. The feeding device prevents the honeybees from drowning in the liquid syrup and provides a safe surface for multiple honeybees to land on while open feeding.

A nursery habitat for flying pollinators has an axially-elongated tubular case and a multiplicity of elongated tubes. The case extends between a first end and a second end and defines an axially-elongated hollow tunnel, wherein at least one of the first end or the second end is provided with an opening. The tubes extending between a front end and a back end wherein at least the front end is open. The multiplicity of elongated tubes is disposed in closely-spaced packing inside the tunnel of the case with the open front ends of the tubes being accessible to flying pollinators through the opening in the case.

A nursery habitat for flying pollinators has an axially-elongated tubular case and a multiplicity of elongated tubes. The case extends between a first end and a second end and defines an axially-elongated hollow tunnel, wherein at least one of the first end or the second end is provided with an opening. The tubes extending between a front end and a back end wherein at least the front end is open. The multiplicity of elongated tubes is disposed in closely-spaced packing inside the tunnel of the case with the open front ends of the tubes being accessible to flying pollinators through the opening in the case.

Disclosed is an efficient delivery output, for an oxalic acid vaporizer, for use with a hive-mounted vaporizer adapter device to more uniformly distribute hot vapor into an interior of a beekeeping device. The efficient delivery output includes an output body having a proximal end and a distal end, and an oxalic acid vapor passageway extending between the proximal end and the distal end; wherein the proximal end is configured to direct and concentrate oxalic acid vapors received from an oxalic acid reservoir of the oxalic acid vaporizer; and the distal end is configured to deliver the concentrated oxalic acid vapors to a central area of the beekeeping device. The vaporizer adapter device engages with a beekeeping hive. The adapter device includes an adapter body (e.g., a flat plate) having at least one hive engagement feature (e.g., side edges of the plate); at least one manipulation feature (e.g., a lip for gripping a front of the plate); and a recess for providing a reservoir (e.g., a space for the hot acid vapor to gather) below the hive, the reservoir being open to an interior of the hive, the recess including a port (e.g., a through hole) configured to accommodate the efficient delivery output.

Disclosed is an efficient delivery output, for an oxalic acid vaporizer, for use with a hive-mounted vaporizer adapter device to more uniformly distribute hot vapor into an interior of a beekeeping device. The efficient delivery output includes an output body having a proximal end and a distal end, and an oxalic acid vapor passageway extending between the proximal end and the distal end; wherein the proximal end is configured to direct and concentrate oxalic acid vapors received from an oxalic acid reservoir of the oxalic acid vaporizer; and the distal end is configured to deliver the concentrated oxalic acid vapors to a central area of the beekeeping device. The vaporizer adapter device engages with a beekeeping hive. The adapter device includes an adapter body (e.g., a flat plate) having at least one hive engagement feature (e.g., side edges of the plate); at least one manipulation feature (e.g., a lip for gripping a front of the plate); and a recess for providing a reservoir (e.g., a space for the hot acid vapor to gather) below the hive, the reservoir being open to an interior of the hive, the recess including a port (e.g., a through hole) configured to accommodate the efficient delivery output.

A preferred embodiment provides a reconfigurable and removable cover securely fixed to an exterior of a hive structure. The preferred material of the cover provides both temperature and humidity control through use of various layers which allow proper air flow. Temperature control is provided by a novel combination of heat absorptive and heat reflective layers and surfaces. A reduction of heat loss in the hive structure reduces the amount of energy required to keep the hive at the desired temperature thereby preserving food resources and preventing colony collapse. The heat reflective layers cool the hive in the summer by reflecting solar radiation.

A preferred embodiment provides a reconfigurable and removable cover securely fixed to an exterior of a hive structure. The preferred material of the cover provides both temperature and humidity control through use of various layers which allow proper air flow. Temperature control is provided by a novel combination of heat absorptive and heat reflective layers and surfaces. A reduction of heat loss in the hive structure reduces the amount of energy required to keep the hive at the desired temperature thereby preserving food resources and preventing colony collapse. The heat reflective layers cool the hive in the summer by reflecting solar radiation.

There is provided herein an universal inner cover for a beehive which has a plate having a perimeter, and an upper surface and an opposing lower surface; and, a housing which is disposed on the upper surface of the plate having a perimeter which is smaller than the perimeter of the plate and which has four interconnected side sidewalls which are orthogonal to the upper surface of the plate. The plate's upper surface can be convex and the opposing lower surface can be convex. The housing can have a layer of insulation disposed therein, which can optionally contain cut-outs to hold various components for beehives.

There is provided herein an universal inner cover for a beehive which has a plate having a perimeter, and an upper surface and an opposing lower surface; and, a housing which is disposed on the upper surface of the plate having a perimeter which is smaller than the perimeter of the plate and which has four interconnected side sidewalls which are orthogonal to the upper surface of the plate. The plate's upper surface can be convex and the opposing lower surface can be convex. The housing can have a layer of insulation disposed therein, which can optionally contain cut-outs to hold various components for beehives.