GRID RING BROOD COMB FRAME FOR CYLINDRICAL BROOD CHAMBER HIVES

Abstract

The present invention relates to a grid ring brood comb frame for cylindrical brood chamber hives, which has a brood comb frame (20) carrying the comb (6), and the brood comb frame (20) is supplied with connection bodies (40) for connection to the rotating structure. The characteristic feature of the invention is that a grid ring (30) is located at least partially running around the external shell surface (21) of the brood comb frame (20) carrying the comb (6) opposite to the comb (6), where the brood comb frame (20) and the grid ring (30) are connected to each other via connection sections (31), the grid ring (30) is supplied with a first edge (32) extending beyond the longitudinal external plane (S) resting on the first side surface (22) of the brood comb frame (20), the height (M) of the first edge (32) measured from the longitudinal external plane (S) of the brood comb frame (20) is between 18 mm, furthermore the connection sections (31) between the brood comb frame (20) and the grid ring (30) are interrupted by one or more bee spaces (34), where the radial dimension of the bee space (34) is between 425 mm.

Claims

1-12. (canceled)

13. A grid ring brood comb frame for cylindrical brood chamber hives, the brood comb frame carrying a comb and being supplied with connection bodies for connection to a rotating structure, wherein a grid ring is located at least partially running around an external shell surface of the brood comb frame carrying the comb and opposite to the comb, the brood comb frame and the grid ring being connected to each other via connection sections, the grid ring being supplied with a first edge extending beyond a longitudinal external plane (S) resting on a first side surface of the brood comb frame, wherein a height (M) of the first edge measured from the longitudinal external plane of the brood comb frame is in a range of 18 mm, and the connection sections connecting the brood comb frame and the grid ring are interrupted by at least one bee space, and wherein a radial dimension of the bee space is in a range of 425 mm.

14. The grid ring brood comb frame according to claim 13, wherein the grid ring has a second edge extending beyond the longitudinal external plane (S) resting on a second side surface of the brood comb frame, and a height (M) of the second edge measured from the longitudinal external plane (S) resting on the second side surface of the brood comb frame is in a range of 18 mm.

15. The grid ring brood comb frame according to claim 14, wherein a number of connection bodies belonging to one grid ring brood comb flame is three, and the individual connection bodies are arranged in a vicinity of an external side of the grid ring at a centre-point angle () in a range of 80160 from each other.

16. The grid ring brood comb frame according to claim 15, wherein the first connection body is supplied with a stop piece while, apart from this, at least one further connection body has a locking piece suitable for receiving a brood frame support of the cylindrical brood chamber hives.

17. The grid ring brood comb frame according to claim 16, wherein one of the connection bodies has a support piece suitable for connection to a rotation axle serving to swing out the grid ring brood comb frame.

18. The grid ring brood comb frame according to claim 17, wherein the grid ring brood comb frame is coupled with a sealing body, and the sealing body is supplied with an internal surface corresponding to a size and shape of an edge located on the grid ring of the grid ring brood comb frame, and facing a direction of the edge.

19. The grid ring brood comb frame according to claim 16, wherein the grid ring brood comb frame is coupled with a sealing body, and the sealing body is supplied with an internal surface corresponding to a size and shape of an edge located on the grid ring of the grid ring brood comb frame, and facing a direction of the edge.

20. The grid ring brood comb frame according to claim 14, wherein the grid ring brood comb frame is coupled with a sealing body, and the sealing body is supplied with an internal surface corresponding to a size and shape of an edge located on the grid ring of the grid ring brood comb frame, and facing a direction of the edge.

21. The grid ring brood comb frame according to claim 20, wherein, when the grid ring brood comb frame and the sealing body are in their installed position, an internal gap-distance (T) between an external rim of the first edge of the grid ring brood comb frame and an external rim of the second edge of the grid ring brood comb frame is in a range of 2-12 mm, and an external gap-distance between at least one of the external rim of the first edge of the grid ring brood comb frame and the external rim of the second edge of the grid ring brood comb frame, on one side, and an internal surface of the sealing edge of the sealing body, on another side, is in a range of 4-15 mm.

22. The grid ring brood comb frame according to claim 13, wherein a number of connection bodies belonging to one grid ring brood comb frame is three, and the individual connection bodies are arranged in a vicinity of an external side of the grid ring at a centre-point angle () in a range of 80160 from each other.

23. The grid ring brood comb frame according to claim 22, wherein a first connection body is supplied with a stop piece while, apart from this, at least one further connection body has a locking piece suitable for receiving a brood frame support of the cylindrical brood chamber hives.

24. The grid ring brood comb frame according to claim 22, wherein one of the connection bodies has a support piece suitable for connection to a rotation axle serving to swing out the grid ring brood comb frame.

25. The grid ring brood comb frame according to claim 22, wherein the grid ring brood comb frame is coupled with a sealing body, and the sealing body is supplied with an internal surface corresponding to a size and shape of an edge located on the grid ring of the grid ring brood comb frame, and facing a direction of the edge.

26. The grid ring brood comb frame according to claim 13, wherein the grid ring brood comb frame is coupled with a sealing body, and the sealing body is supplied with an internal surface corresponding to a size and shape of an edge located on the grid ring of the grid ring brood comb frame, and facing a direction of the edge.

27. The grid ring brood comb frame according to claim 26, wherein, when the grid ring brood comb frame and the scaling body are in their installed position, an internal gap-distance (T) between an external rim of the first edge of the grid ring brood comb frame and an external rim of a second edge of the grid ring brood comb frame is in a range of 2-12 mm, and an external gap-distance between at least one of the external rim of the first edge of the grid ring brood comb frame and the external rim of the second edge of the grid ring brood comb frame, on one side, and an internal surface of the sealing edge of the sealing body, on another side, is in a range of 4-15 mm.

28. The grid ring brood comb frame according to claim 13, wherein the grid ring has at least three spacer pieces protruding from at least one of the first edge and a second edge of the grid ring, and each individual spacer piece is regularly arranged along a given edge of the grid ring.

29. The grid ring brood comb frame according to any of claim 13, wherein the brood comb frame has an internal cavity and a heating part-unit located in the internal cavity, and the heating part-unit has a heating element made from electrical resistance wire and connection extensions leading out to the external shell surface of the brood comb frame.

30. The grid ring brood comb frame according to claim 13, wherein the comb located in the brood comb frame is at least partially formed from a multitude of bee cells, each bee cell being delimited by a cell wall with a regular hexagonal cross-section and a cell base, at least some of the cell walls being formed as a pro-pressed wax design with a wall thickness (V) of 12 m, wherein a protrusion (K) of at least some of the cell walls formed from the wax design is at least 3 mm, and a longitudinal axis of the hexagonal cross-section cell wall is in a perpendicular position relative to a main plane (FS) of the comb.

31. The grid ring brood comb frame according to claim 30, wherein, among the bee cells forming the comb, bee cells with differing sizes of cross-sectional area and/or shape are arranged in an inner zone of the comb and in an outer zone of the comb, and a size of the cross-sectional area of the bee cells located in the inner zone is greater than a size of the cross-sectional area of the bee cells located in the outer zone.

32. The grid ring brood comb frame according to claim 13, wherein material of the comb is formed by beeswax, and stiffening inserts are located scattered in the beeswax forming the material of the comb.

Description

[0046] In the following the grid ring brood comb frame according to the invention is presented in more detail in connection with embodiments, on the basis of drawings. In the drawings

[0047] FIG. 1 is a cross-sectional side-view picture of a possible version of a cylindrical brood chamber hive using the grid ring brood comb frame according to the invention,

[0048] FIG. 2 shows the front view picture of a version of the grid ring brood comb frame,

[0049] FIG. 3 shows the cross-section taken on the plane III-III according to FIG. 2,

[0050] FIG. 4 shows the cross-section taken on the plane IV-IV of the grid ring brood comb frames assembled in a cylindrical brood chamber hive according to FIG. 1,

[0051] FIG. 5 is a detail of the front view picture of the comb visible in FIG. 2,

[0052] FIG. 6 is a detail of the comb visible in FIG. 3.

[0053] In FIG. 1 the longitudinal cross-section picture of a hive 1 also containing the grid ring brood comb frame 4 according to the invention may be seen. It may be observed that the delimiting shell 1a of the hive 1 encloses the brood chamber cavity 1b, in which the grid ring brood comb frames 4 accommodating the comb 6 bordered by the grid ring 30 are located. The grid ring brood comb frames 4 are connected to the rotation structure 4anot illustrated in FIG. 1connected to the delimiting shell 1a of the hive 1 so that it may rotate with the mediation of the connection bodies 40 associated with the grid ring 30.

[0054] FIG. 1 also shows that the cross-sectional size of the bee cells 9 of the comb 6 located in the grid ring 30 of the grid ring brood comb frame 4 is larger in the inner zone 7 of the comb 6 than in the outer zone 8 of the comb 6.

[0055] FIGS. 2 and 3 show a possible version of the grid ring brood comb frame 4 according to the invention. It may be observed that the comb 6 is located in the circular ring shaped brood comb frame 20 in the usual way, which in this case is made from a natural material, beeswax. The grid ring brood comb frame 4 according to the invention fundamentally differs from the known versions in that the grid ring 30 encompasses the brood comb frame 20 of the grid ring brood comb frame 4 on the external shell surface 21 of the brood comb frame 20 in such a way that the connection sections 31 are located between the external shell surface 21 of the brood comb frame 20 and the internal side 36 of the grid ring 30. The connection sections 31 ensure a permanent sized gap t of at least four millimetres but at the maximum twelve millimetres between the external shell surface 21 of the brood comb frame 20 and the internal side 36 of the grid ring 30. The size of the gap t in this case is eight millimetres. Here the brood comb frame 20, the grid ring 30 and the connection sections 31 are made of a single material, plastic, by injection moulding.

[0056] FIG. 3 well illustrates that between the connection sections 31 connecting the brood comb frame 20 to the grid ring 30 there are bee spaces 34 bordered by the external sell surface 21 of the brood comb frame 20, the internal side 36 of the grid ring 30 and by two sets of two neighbouring connection sections 31 arrange in a specific order along the external shell surface 21 of the brood comb frame 20. The radial size m of these bee spaces 34 is between 412 mm, in the interest of the drones, the workers and the queen being able to pass through them from the first side surface 22 of the brood comb frame 20 of the grid ring brood comb frame 4 to the second side surface 23. The first side surface 22 and the second side surface 23 of the brood comb frame 20 actually form two constructed bee cell structured sides of the comb 10 located in the brood comb frame 20. In this case the radial size m of the bee spaces 34 and the gap t ensured by the connection sections 31 are the same.

[0057] FIG. 3 also illustrates that the grid ring 30 has a first edge 32 protruding from the external plane S resting on the first side surface 22 of the brood comb frame 20. Here the height M of the first edge 32 from the first side surface 22 of the brood comb frame 20 to the external rim 32a of the first edge 32 may be between 18 mm. It may also be observed thatin the case of this versionthe grid ring 30 has a second edge 33 protruding from the external plane S falling on the second side surface 23 of the brood comb frame 20. The height M of this second edge 33 between the external plane S of the second side surface 23 of the brood comb frame 20 and the external rim 33a of the second edge may also be between 18 mm.

[0058] The internal shell surface 24 of the brood comb frame 20 facing the comb 6 is structured in such a way that it is easily capable of accommodating and retaining the comb 6. Here it must be noted that in the interest of the simple and secure retention of the comb 6 the brood comb frame 20 forming a single unit with the grid ring 30 may consist of two or more pieces. In the case of this embodiment the brood comb frame 20-grid ring 30 unit is preferably constructed from two halves, which two halves enclose the central wall of the comb 6.

[0059] In the case of the given embodiment the internal cavity 25 may be found in the part delimited by the two half pieces of the brood comb frame 20, which internal cavity contains the heating part-unit 10. The heating part-unit 10 consists of a heating element 11 and of connection extensions 12. Here the heating element 11 runs completely around the torus-like internal cavity 25 of the brood comb frame 20. Also the connection extensions 12 run out in the vicinity of the stop piece 41 to the external side 35 of the grid ring 30 of the brood comb frame 20 in the interest of being able to feed an electric current into the heating element 11 of the heating part-unit 10 in the internal cavity 25 of the brood comb frame 20. In this way with the help of a suitable control device the heating element 11 of the heating part-unit 10 is capable of slowly, precisely heating the cylindrical brood chamber 38 and the entire brood chamber of the hive 1indicated in FIG. 4and maintain it in the given, narrow temperature range, with the help of which pest control is also solved.

[0060] Returning now to FIG. 2, on it, it can be seen that the grid ring 30 in the present embodiment, the connection bodies 40 are located in the vicinity of the external side 35 of the grid ring 30, the task of which is to keep together the grid ring brood comb frames 4 lined up next to one another as a single unit. Among the connection bodies 40 the firstwhich in this case is located on the left side of FIG. 2is the stop piece 41, the second is the locking piece 42 and the third is the supporting piece 43. The task of the stop piece 41 is to retain the given grid ring brood comb frame 4 with the help of the brood frame support 2 cooperating with it, and to not permit it to tilt to the left around the rotation axle 3 fitted into the supporting piece 43. The task of the supporting piece 43 is, in cooperation with the rotation axle 3 threaded into itin the case of the arrangement visible in FIG. 2to make it possible for the grid ring brood comb frame 4 to rotate around the rotation axle 3 to the right when the brood frame support 2 is not positioned in the locking piece 42. While the locking piece 42 serves to retain the grid ring brood comb frame 4 in its operation position in the case of the positioning of the brood frame support 2 threaded through it, while when the brood frame support 2 is in its pulled-out state it is to make it possible for the grid ring brood comb frame 4 to tilt to the right around the rotation axle 3 in the supporting piece 43in the state shown in FIG. 2.

[0061] It may also be easily seen in FIG. 2 that the stop piece 41, the locking piece 42 and the supporting piece 43 of the connection bodies 40 are located at a centre-point angle of 120 as compared to one another. Naturally, an arrangement deviating from that presented in FIG. 2 may also be imagined, the essence is for the brood frame supports 2 and the rotation axle 3 to be located around the grid ring 30 of the grid ring brood comb frames 4 so that the grid ring brood comb frames 4 are easily and securely fixed to one another, but in the interest of the handling of the individual grid ring brood comb frames 4, so that their removal may be realised simply and quickly.

[0062] The spacer pieces 37 are also located next to the connection bodies 40 around the grid ring 30 of the grid ring brood comb frame 4. These space pieces 37 may be combined with the connection bodies 40 but they may also be independent as well. In any case their task is to fix the grid ring brood comb frames 4 located next to one another in the desired position.

[0063] FIG. 2 also illustrates that in this case the comb 6 is made from a natural material, here from beeswax 6a. It may be seen that the cross-section size of the bee cells 9 in the inner zone 7 of the comb 6 is greater than the cross-section size of the bee cells 9 in the outer zone 8 of the comb 6. Here, the bee cells 9 for drones are located in the inner zone 7 of the comb 6 and the bee cells 9 suitable for worker bees are located in the outer zone 8 of the comb 6. There is a transitional ring running between the inner zone 7 and the outer zone 8. Here it must be noted that the size of the inner zone 7 and the outer zone 8 and the ratio of their surfaces as compared to each other determines the development of the sex ratio of the bee colony, after the development of the eggs of the comb 6 also influencing the given sex ratio.

[0064] Moving over to FIG. 4, this presents an arrangement in the case of which the grid ring brood comb frame 4 are lined up next to one another with the help of the brood frame supports 2 and the rotation axle 3, and in this way they are located into the rotating structure 4a, which is connected to the delimiting shell 1a of the hive 1.

[0065] It may be seen that between two neighbouring grid ring brood comb frames 4, as a result of the spacer pieces 37 resting on one another, an internal gap distance T is formed between the first edge 32 of the grid ring 30 of the one grid ring brood comb frame 4 and the second edge 33 of the grid ring 30 of the neighbouring other grid ring brood comb frame 4, the value of which between the external rim 32a of the first edge 32 and the external rim 33a of the second edge 33 is between 2-12 mm. Here, preferably, 4.2 mm.

[0066] It may also be seen in FIG. 4 that beside the grid ring brood comb frames 4, at each of the two outermost positions there is a sealing body 5 threaded in the cylindrical brood chamber 38 installed in the hive 1 with the help of the brood frame supports 2 and the rotation axle 3. The sealing body 5 has a sealing edge 5a, the size and shape of which conforms to the first edge 32 and to the second edge 33 of the grid ring brood comb frame 4 next to it. The external gap distance Ti between the internal surface 5b of the sealing edge 5a of the sealing body 5 and the external rim 32a of the first edge 32 of the neighbouring grid ring brood comb frame 4 or the external rim 33a of the second edge here is between 4-15 mm, but preferably 8 mm.

[0067] In FIG. 5as presented in FIG. 2the front view of a piece of the comb 6 located in the brood comb frame 20 belonging to the grid ring brood comb frame 4 may be seen. It may be observed that the comb 6, which in this case is made from a natural material, from beeswax 6a, is constructed from bee cells 9 which have a regular hexagonal cross-sectional bee cell wall 9a and a cell base 9c bordering it from the bottom.

[0068] FIG. 6 presents a detail of the cross-section of the comb 6 according to FIG. 3. Here the bee cells 9 lined up next to one another are easily visible; these are formed from the set of cell walls 9a and cell bases 9c. It may also be easily observed that the longitudinal axis 9b of the bee cell 9 and the main plane FS of the comb 6 are perpendicular to one another. The longitudinal axis 9b is, at the same time, the axis of symmetry of the cell wall 9a as well. The wall thickness V of the cell wall 9a of the bee cell 9 here is at least 12 m, while the protrusion K of the cell wall 9a from the main plane FS of the comb 6 is at least 6 mm. Such combs 6 with a cell structure preferably established from a natural material, beeswax 6a with such geometrical dimensions on the basis of acquired experience are suitable for the bees to accept them, complete them, adjust them and use them. It is also an important circumstance that stiffening inserts 6b are located in the natural material of the comb 6, which further improves the usability of the comb 6.

[0069] In a hive 1 fitted with the solutions according to the invention, during the use of the grid ring brood comb frame 4 first of all it is possible to install the individual grid ring brood comb frames 4 lined up next to one another between the stably fitted left-side brood frame support 2 connected with the sealing bodies 5 located in the hive 1 and connected to the rotating structure 4with respect to the status according to FIG. 2and the rotation axle 3, and then thread them with the help of the right side brood frame support 2. Following this the cylindrical brood chamber 38 consisting of the grid ring brood comb frames 4, the two sealing bodies 5 as well as the brood frame supports 2 and the rotation axle 3 threading these is now fitted in the hive 1 so that it may even rotate.

[0070] In order to inspect, handle or just to view a given grid ring brood comb frame 4 the brood frame support 2 fitted into the locking piece 42 and fixed in the sealing bodies 5 must be removed from the locking piece 42. At this time the given grid ring brood comb frame 4 may be swung out from among the rest of the grid ring brood comb frames 4 around the rotation axle 3 running through the supporting piece 43, and in this way the sides of the comb 6 of the given grid ring brood comb frame 4 may be inspected from the aspect of the first side surface 22 and the second side surface 23 of the brood comb frame 20. After inspection the given grid ring brood comb frame 4 may be swung back around the rotation axle 3 until the stop piece 41 located on the grid ring 30 of the grid ring brood comb frame 4 reaches the brood frame support 2, where it stops.

[0071] With the grid ring brood comb frame 4 in this position the locking piece 42 of the grid ring brood comb frame 4 gets into a coaxial position with the locking pieces 42 of the other grid ring brood comb frames 4, and in this way the brood frame support may again be fitted into the locking piece 42 of the swung back grid ring brood comb frame 4 and in this way the given grid ring brood comb frame 4 may be fixed.

[0072] The grid ring brood comb frame 4 according to the invention and the novel structured comb 6 may be used to good effect in all cases when in the case of rotating cylindrical brood chamber hives easy, fast and safe brood chamber handling, the protection of the individuals of the bee colony in the hive, the planned regulation of the sex ratio of the colony and the strengthening and effective productivity of the colony are desired.