A device to form a honeycomb has an upper continuous belt and a lower continuous belt disposed in parallel and carrying opposing cores. The belts act on liquid wax which is injected into an inlet of the device, with both belts moving in opposition. The inlet has in succession: a scraping zone disposed straight with respect to the upper belt; a zone for opening the cores, which has a certain curvature designed to receive a first injection of wax; and a third straight zone for sealing and expelling any excess wax. At an exit of the device, the longest length of the upper belt has multiple groups of magnetic and non-magnetic rollers for a local curving of the belt to progressively release the honeycomb.

A device to form a honeycomb has an upper continuous belt and a lower continuous belt disposed in parallel and carrying opposing cores. The belts act on liquid wax which is injected into an inlet of the device, with both belts moving in opposition. The inlet has in succession: a scraping zone disposed straight with respect to the upper belt; a zone for opening the cores, which has a certain curvature designed to receive a first injection of wax; and a third straight zone for sealing and expelling any excess wax. At an exit of the device, the longest length of the upper belt has multiple groups of magnetic and non-magnetic rollers for a local curving of the belt to progressively release the honeycomb.

A splittable honeycomb comprising: a first comb portion and a second comb portion comprising a first series of cell portions and a corresponding second series of cell portions respectively, said first and second cell portions defining a series of honeycomb cells therebetween, the first comb portion and the second comb portion being moveable relative to each other from a closed cell position to an open cell position, wherein mutually opposed edges of said cells are non-contiguous in the closed cell position to thereby avoid catching a limb of a bee.

A splittable honeycomb comprising: a first comb portion and a second comb portion comprising a first series of cell portions and a corresponding second series of cell portions respectively, said first and second cell portions defining a series of honeycomb cells therebetween, the first comb portion and the second comb portion being moveable relative to each other from a closed cell position to an open cell position, wherein mutually opposed edges of said cells are non-contiguous in the closed cell position to thereby avoid catching a limb of a bee.

An artificial honeycomb for use in a beehive and which enables honey to be removed from the honeycomb without removing the honeycomb from the hive, the honeycomb comprising cells and being formed of at least two parts which are moveable relative to each other between a cell formed position where the cells comprise side walls and an end wall to enable bees to fill the cell with honey, and a cell open position where at least some of the said walls have moved apart, whereby honey in the cells can be removed from the honeycomb by movement of the at least two parts to the cell open position.

An artificial honeycomb for use in a beehive and which enables honey to be removed from the honeycomb without removing the honeycomb from the hive, the honeycomb comprising cells and being formed of at least two parts which are moveable relative to each other between a cell formed position where the cells comprise side walls and an end wall to enable bees to fill the cell with honey, and a cell open position where at least some of the said walls have moved apart, whereby honey in the cells can be removed from the honeycomb by movement of the at least two parts to the cell open position.

The frame (1) with sensors (3) for sampling the contents of the honeycomb based on the method of absorption spectroscopy, includes a honeycomb foundation (2) within which are sensors (3) connected by a parallel bundle of wires (4) to a central microprocessor unit with memory (5) which is connected to the power supply unit (6) and the communication subsystem (7) so that the behavior of the bees and the usual manipulation of the beekeepers are preserved. The system refers to the field of application of electrical engineering for monitoring biological systems, and specifically to sensory monitoring of bee colonies by determining the content of honeycombs within the brood chamber of the frame. The system finds application in beekeeping for non-invasive remote control of bee colonies in the subject hive.

A beehive suitable for the treatment of a colony of bees inside it against the infestation of mites, includes a plurality of frames for supporting honeycombs. The frames do not have pre-built honeycombs to house the eggs of the bees, so that they are built by the bees to suit their needs. The frames are able to be heated inside the beehive, up to a maximum temperature of less than 45 C.

As described below, the present invention features methods and compositions for controlling a honey bee parasitic mite or for the treatment or prevention of a parasitic mite infestation in a honey bee hive. In particular embodiments, the invention provides a miticidal delivery device, wherein the device is a corrugated strip comprising a liquid composition comprising at least about 15% potassium salts of hop beta acids, solvent and an emulsifier.

As described below, the present invention features methods and compositions for controlling a honey bee parasitic mite or for the treatment or prevention of a parasitic mite infestation in a honey bee hive. In particular embodiments, the invention provides a miticidal delivery device, wherein the device is a corrugated strip comprising a liquid composition comprising at least about 15% potassium salts of hop beta acids, solvent and an emulsifier.