LV13344B - Bee-hive and its arrangement in the container - Google Patents

Abstract

The invention refers to beekeeping. The hive offered is characterized by: a ventilation recess 18A connecting the space of bees nest under floor 1, which is provided with chamber 2 for ventilation and moisture condensation; the said recess is formed beneath the entrance floor and all over its length and width is provided with a removable ventilation net 9; a ventilation damper 8 meant for control of recess 18A is suspended from outside against the said net; the floor of the hive can be shifted and removed after removal of the case and is provided with a conic extension, which extends from internal hive's frame wall that is located opposite to the floor, as far as the entrance; a podium of floor sloped towards the upper plane 7 of the floor is formed under the entrance; the floor is thermo- and hydro-isolated. The height of every wall in the multi-case hive is greater then its width, and the area of horizontal cross-section of the case is chosen appropriate to an average diameter of bees' ball in winter time; junctions of constituents of the hive's outer walls slope outwards; planes 4 and 6 of the floor and partially the floor plane 5 of entrance is covered by a thick polyethylene film 4A as far as the recess 18A, which all over its width is covered by the ventilation net 13A that by one side is fastened to an edge of polyethylene film. Arrangement of hives in a displaceable container of pavilion type is characterized in that entrances of hives indoors are turned in the opposite directions; flying-out of bees is ensured through recess formed in the floor of the container; entrances sideways above the floor are delimited by partitions, which above the entrances are covered by sheets of glass or acrylic plastic forming a roof. Figure annexed shows the lateral section of multi-case hive inserted into the container.

Description

Description of the Invention

The invention relates to all standard bee hives. It aims to improve the microclimate in the bee nest and to ensure that the hive is compatible with open-air horticulture, as well as with traveling industrial or backyard beekeeping, while reducing bee handling and increasing the number of hives in a container or pavilion

Analysis of known information

The most widespread in the world is the multi-body hive. It is vertical and there is no limit to the size of the bee nest, and the beekeeper does not work with individual frames, as in a sleeping hive, but with shells. Therefore, the present invention will contemplate a multi-hive hive, where strong bee colonies can be established and larger hives can be housed in containers or pavilions. The bees need air in the summer as well as in the winter to inhale oxygen and to release carbon dioxide. The microclimate in the hive has a strong influence on bees: their physiological state, productivity, productivity. The intensity and amount of gas exchange in the bee fluctuates both with the time of year and with the size of the beehive in the hive. The flow of air between the cells as the bees' bodies move with warm air from the bottom up reaches each bee and brood. During the season, regardless of the outside temperature, the hive should not exceed 35 ° C and the average humidity should be between 75% and 80%. The body temperature of a bee, when it is at rest, differs little from the outside temperature. Bees lower the temperature by releasing water from the body. If temperatures rise from 10 to 30 ° C outside the nest, bees use 57 times more oxygen, i. more oxygen is used for metabolism. The bees maintain an average temperature of 33.5 ° C to heat the bee brood.

The internal temperature effect on bees in hibernation is shown in Fig. 1, where the upper row shows the cross-sectional and longitudinal distribution of the bees in the interstellar space and the lower row shows the movement of the bees in the interstellar space from the beginning (a) to the end. In the bees, in the beginning of the wintering period, the bees form a ball near the lower runway, where fresh air with oxygen flows in. As can be seen during the wintering process, bees in the nest avoid low temperatures by moving farther up the run. It is affected by the heat distribution of the socket and the flow of cold air. The warm air exiting the bee ball covers the entire ball on all sides. When a bee ball winters on 8 bee cells and runs 8 cm wide, the cold air in the winter flows through the runner in the immediate vicinity of the ball, cooling the warm air over a large area. In addition, the bees are strongly exposed to direct air convection and concentration of carbon dioxide in the lower part of the nest, in close proximity to the floor and low open run. In a bee nest with a larger amount of honey, with vertical, long cells in a tree cavity or a hive with tall and narrow frames, such as Ukrainian sleeper frames, bees release honey for cold isolation from the cold. Moving upwards and maintaining the correct diameter of the ball, the bees use less energy for heating because the edge of the ball is adjacent to the shell walls. The average bee wintering ball for a normal bee colony is 250300 mm. There is usually free space under the bee ball in the wooden cavity, in which case air circulation is better and the bulb has a normal degree of humidity. This process has taken place in bee colonies over a long period of evolution in temperate and cold climates. This is also due to the fact that: the larger the horizontal cross-section of the bee nest, the greater the loss of heat and energy for the bees. Bees usually maintain a temperature of 24 to 28 ° C inside the ball. The passive period of bee life is characterized by high inequalities in the distribution of water vapor in the bee nest. The humid air gradient begins to increase in the fall when the outside temperature begins to decrease. This stimulates the bees to gather together more densely. The uneven distribution of water vapor in the bee nest continues throughout the winter. In the part of the nest occupied by bees, the greatest localization of water vapor occurs in the heat center. Moving from the center to the runway, the lower part of the socket is drastically reduced. The saturation of the water vapor in the various parts of the nest occupied by the bees and in the open areas depends on the temperature and humidity of the outside air entering the nest, the aeration of the air and the physiological state of the bees. At the beginning of winter, at an ambient temperature of 0 ° C, the absolute humidity in the non-brood nest is within the range of 10-20 g / m ³ . In this condition the degree of humidity varies between 38-70%. The presence of Peru in the second half of the winter is exacerbated by low-level humidity fluctuations, but the upper limit only increases with the end of winter. Over a wide range, the humidity of the air fluctuates in the part of the nest which is not occupied by bees, especially in the run area. In this part of the nest, including the interstellar free nest space, which is not occupied by the bees' saturation of the air with water vapor, changes according to the variation of the outside air. Temperature and humidity, as a result of the outside air, strongly affect the socket area of the impingement wall. Air humidity in this part of the nest quite often remains at full humidity saturation. When the temperature drops, steam condenses in the form of water. Condensation can occur in large quantities not only on the floor and back wall, but also in the bee cells present. Of course, by installing through-pass ventilation in the bee hive, moisture is removed, thereby removing warm air from the bee nest. Despite the excessive humidity in this nesting area, the water saturation of a strong island decreases to one tenth of a gram per m ^{3 of} air volume. Between the different areas of the nest, which are not occupied by bees, the upper part differs with the highest humidity stability, especially the one above the heat center. This area is also characterized by high water vapor saturation in air compared to other areas of the bee nest area not occupied by bees. The only difference is during the thaw, when warm air enters the socket, concentrating on the rear hive wall. The maintenance of water vapor in the upper part of the nest above the bees during the passive life of the bees varies slightly: 81 ± 1.79% in the autumn months, -74 ± 1.2% in the winter months, and decreases to 3% on average in March and April.

Bee life is greatly influenced by the concentration of oxygen and carbon dioxide in the bee nest. As a result of the air exchange with the outside air, the bee nozzle enters the air with the air, but carbon dioxide, heavier than air, is discharged. In the bee nest, the zonal gradient in oxygen and carbon dioxide varies with the activity of the bee and with the time period, the lifestyle of the bee colony. The minimum difference between these gases in the bee nest reaches in the second half of the summer, when warm weather occurs. During this time, the concentration of carbon dioxide in the center of the nest is 0.35%, while the concentration of oxygen is 19.9%, but in September in these zones the concentration of carbon dioxide is 1.1%. The same thing happens in April and the concentration of carbon dioxide changes from the outside air temperature. At the beginning of spring, when the outside temperature is -3 to + 9 ° C, the concentration of carbon dioxide in the central part of the nest is in the range of 1.8-3.7% and the concentration of oxygen is around 6%. As the outside air temperature rises, the carbon dioxide decreases, but the oxygen concentration increases.

The bee colonies are worried about transportation. It has been found that new bees for up to 17 days engaged in roach feeding, along with many other bees, leave the nest and move into the space above the nest with a sieve for ventilation. As a result, the upper sieve is sealed and the concentration of carbon dioxide in the bee nest increases rapidly to 4%. The bee's breathing time (cycle duration) is very different from the bee activity. At low activity it amounts to 40-60 changes of direction per minute and at high activity it is 130-150. As the bee activity decreases, the amount of oxygen in the nest decreases, the humidity level increases 1.5 times, and the amount of carbon dioxide increases on average 5 times. By increasing the concentration of carbon dioxide in the nest, the bees encourage the ventilation of the air with the help of wings. An important factor influencing the condition of bees, their physiological wear, and their physiological age is the amount of work to be done. For example, in natural life, bees wear out faster when raising their brood. This demonstrates the need to protect bee colonies from the effects of low or high temperatures throughout their lives. Proper hydration is maintained by providing proper ventilation in the hive and avoiding elevated concentrations of carbon dioxide. As the outside temperature approaches 40 ° C, the water consumption of the bee colony increases so much that all the flying bees start to supply water. For this reason, other bees in the nest are forced to leave the nest by exiting the hive, but to save the nest from being overheated, the remaining bees in the hive are forced to increase ventilation in the hive. The degree of humidity is of great importance for bee worm feed. If a cell is isolated from bees, their food will dry out or turn into a thickened mass within 1-2 hours, resulting in the death of the worms. Many test results have shown that humidity in the bee nest is needed at all times of the year for both working bees, and for worms and broods.

An important role in the life of bees is played by the hydrological regime in the hive. Water vapor in the hive can move in water or ice at natural changes in atmospheric pressure and temperature. Maximum saturation of water vapor in air at normal atmospheric pressure increases with temperature: at 1 ° C 4.84 g of water is required to saturate 1 m ^{3 of} air, at 20 ° C - 17.32 g, at 39 ° C - 48.2 g. Vapor saturation at constant temperature and pressure is in equilibrium with the water surface. Raising or lowering the temperature destroys this equilibrium, condenses part of the water vapor, or additionally traps the water in the evaporated place.

It is known that dew drop is usually formed in humid saturated air, for example at a temperature of 8 ° C on a cooled surface where the temperature should be lower than the air temperature. During the active period of the bee, during the development of the bee colony, the humidity in the middle zone with a moderate climate is affected at different places in the nest: outside temperature, saturated air with a certain amount of water and the degree of humidity of the feed. In summer, the external humidity ranges from 25-100%. The minimum humidity is affected by the outside air temperature. For example, in the summer, in the middle zone night and day temperatures range from 10 to 25 ° C, outside air humidity ranges from 50 to 100%, and bee hives typically range from 38 to 85%.

Bee hive plays a big role in the ventilation limitations of the outside air. In order to intensify the air exchange, sieves are installed in the bee nest on the roof of the hive to remove damp air. The hive over the socket is covered with a thermally insulated material with a vent, or pillows with a heat insulating material. In these variants, external cold air flows through the hive runner, while wet and warm air flows through the insulated ceiling. Beekeepers are forced to do this to avoid mold and excessive humidity, but ventilation also has a major downside: when the wet air passes through the ceiling, it releases the warm air needed to heat the bees. It does not occur in a wooden cavity where the humid air is partially absorbed by the decaying part of the wood wall, but the rest of the humid air under the bee ball in the free space, along with the carbon dioxide, cools and dissipates when combined with atmospheric air. In this case, direct contact of warm air with cold air is interrupted. It is interrupted by the placement of the bees between two different temperatures, with the bee nest only being cooled down

The practice of using hinged roofs with ventilation mesh indicates that rapid steam condensation occurs in the case of hive ceiling sealing with polyethylene film. In this case, after a few minutes, when the film is cooled by the lower temperature of the outside air, condensation appears under the film. This indicates that the saturation of the air with water vapor reached 100%. In this case, absolute humidity may fluctuate within certain limits depending on the outside temperature, as well as the number of bees per hive unit and its activity. At an external temperature of 20 ° C and with normal bee departure, the average humidity in the upper part of the nest and on the opposite side of the nest is 26 g / m ³ . The location of moisture in the bee nest has been studied by R. Wolgemutom (1957), studying the time at which this is achieved by sealing the ceiling of the special hive. There were three vents in his hive, one in the center of the ceiling and two on the sides. As the apertures were opened, the humidity gradient of the bee nest gradually increased to 30-40%, with the humidity in the brood distribution area opposite to the run at the center of the box height being 50-60% and the brood placement in the run area reaching 70%. Closing the three openings in the ceiling but leaving the runner open, the humidity increased to 76-77% after 10 minutes, and within 40 minutes the humidity stabilized to 93-94%. In addition, the humidity on the opposite side of the run gradually reached 100%. 90% lower humidity was in the run area and stabilized at about 80% after 15 minutes.

In all known multi-body hives, the inter-body free space with wooden frames consists of: a horizontal bar at the top and bottom and a free space of 40 mm. For this reason, the bee colony and the mother do not overcome the natural height of these bees. An adjustable or non-adjustable opening 18 for ventilation, connecting the bee nest space below the floor to the enclosed vent and air condensation chamber 2, extends the flow of the hive within 400-500 mm depending on the width of the hive frame open run size. In the event of a closed run or other need, the bees have the opportunity to leave the nest in the enclosed vent chamber 2 for enhanced ventilation in the bee nest, in addition to which the ventilation of the bee nest in the vent chamber is further regulated by a chamber closure 8.

Summary of the Invention

An adjustable or non-adjustable opening 18 for ventilation, which connects the bee nest space below the floor 1 to the ventilation and air condensation chamber 2, extends the flow of the hive within 400-500 mm depending on the width of the hive frame. , in addition to the ventilation chamber 2, the ventilation of the additional bee nest is regulated by the chamber closure 8.

The sling floor with a ventilation screen, without removing the housing, is slidable and removable with a gradual conical extension from the inner wall of the floor frame to the runway, where a raised underneath the runway ends, ending with a plane of uneven running surface downwards the vertical outer edges of the housing on the inside of the hive to the plane of the sieve 9 are within 15-30 mm, but the width of the vent 18, which may be maximum 10 - 50 mm, is limited by a wide sieve 25 mounted above the ridge or underside; floor outside the sieve, bees can pass into the chamber,

The beehives are housed in a movable pavilion-type container along the exterior walls, with the adjacent hives being run in opposite directions, with the hives being run inside the room, with the bee departing through a floor opening under the floor.

The hive floor 1 at the closed vent opening 18, the lower plane 3 of the floor relative to the lower frame 36 of the frame in the housing, is inclined at 4.5 ° to the running side and the upper plane is parallel thereto.

The floor chamber 2 is formed of a heat-insulated and waterproofed plate, the upper plane 14A of which is parallel to the lower plane 3 of the floor 1.

Multihull hives plastic or wax dummy cells strengthening is placed high and narrow beams the construction aparakstīta Latvian patent LV13313, wherein each hive multihull shell wall height is greater than the width of the housing internal horizontal sectional area of 0,12m ² to average the diameter of the colony of winter bees.

The joints of all the outer walls of the multi-body hive are formed with an outward and downward inclination, while the two vertical walls parallel to the lateral edge of the bee cells are formed in the joints as a half-strap cam and groove fastener.

If the sling floor is not slidable, the floor plane 4 with the raised 6 and partly also the running raised 5 is covered with a thicker polyethylene film 30 mm wide up to the formed opening 18, whereby the ventilation opening 18 is covered with a ventilation mesh edges of polyethylene film.

a brief description of the drawings

The proposed construction of multi-body hives and its components is shown in Fig. 1, which can be used to make both vertical and horizontal multi-body hives.

Fig. 2A shows the hive shown in FIG. 1, section A-A.

Fig. 3A shows a view of the housing shown in Fig. 1; B-B, top view.

Figures 2 and 3 show one part of a pavilion-style beehive container. Mechanical container lifts are installed in the four corners of this container to access the trailer or machine platform below the container. Containers accommodate 12 to 24 multi-body hives, where the two longest walls form multi-body hives. In this row of hives, every other hive is turned with the runner out of the container. Fig.3 shows the location of the hive run towards the room, i.e. the direction of the run is opposite to the direction shown in Fig.2. For these hives, parallel to the two outer walls, the floor has an opening 400 mm long and 40-50 mm wide for the exit of 12 to 24 multi-hulled hives. The flight of the bees to the side of the room in front of each hive is restricted by a wall 42 and covered by a plate of glass or organ glass 43 from above.

To improve the microclimate in the bee nest, taking into account the information above, the height of the multi-body hive shown in Fig. 1 exceeds the width or length of each outer wall. This housing is fitted with tall and narrow frames that are as close as possible to the average diameter of a wintering bee ball (see Latvian Patent LV1331313 Hive Frame; filed March 10, 2005; patent filed July 20, 2005), characterized by a combination of two horizontal and two vertical bars interconnected to form a rectangular structure, each horizontal bar consisting of two vertical lateral planes, the frame having a vertically fixed artificial cell having a thickness center coinciding with the center of the vertical bars and the center of the bee cell, - that the horizontal bars have a thickness equal to the thickness of the bee cell formed vertically between these bars, which enables the bees to sew the wax cell in the remaining free vertical cell, not covered by the horizontal bars, from the vertical plane of the honeycomb; - that in the wooden frame the top and bottom of the bee cell is limited by a thick sheet of polyethylene film and in the plastic frame by a plastic plate the cell is limited from the vertical plane of the cell to the vertical plane of the cell; , which coincide with the vertical lateral plane of the artificial cell; - that a triangular plastic expression is formed at the upper and lower horizontal edges of the frame, which limits the thickness of the embroidered bee cell from the vertical plane to the vertical plane of the plastic artificial cell, similarly to the horizontal laths of the embroidered bee cell. Most importantly, with these frames, beehive multi-hulled beehives eliminate the need to follow bee development during the active season to reposition the enclosures or to limit maternal laying in the lower cortex with the mother's screen, as in such hives the bee family lives similarly to the mother normally moves to work from the upper hull to the lower hull.

The maximum width of the ventilation opening 18 may be within the range of 10-50 mm and one vertical edge of the opening is in one vertical plane with the vertical plane of the inner wall of the floor and the housing. In this vent opening 18 below the floor parallel to the floor plane.3 a curved ventilation screen 13 is attached to the inner wall edge 15 of the floor frame for enhanced ventilation of the chamber below the floor, which is usually done in hot weather without the bee passage in chamber 2. a curvature parallel to the bottom plane 3 of the floor 1, but by expanding the opening with the floor, the bees can leave the nest into the chamber, thus protecting the bee nest from overheating and the increased outflow of carbon dioxide from the hive.

Below the floor run plane 7, a second vent 18A is provided in the width of the floor 1, whereby the vent screen 9 is fixed to the plane 10A and this screen moves along with the floor 1. The screen simultaneously performs the run plane function but has an adjustable triangular closure vent holes 18A for regulating the chamber 2 from top to bottom or vice versa. During the active period of bee life, the latch 8 can be removed from the ventilation sieve and the outlet ventilation can be done by adjusting the opening 18 of the floor 1. Closure 8 is used to regulate the ventilation of the atolls in the colonies. During transport of the apiary, the ceiling cover 27 and the feed container 31 are removed and the bee runner is closed by the latch 8.

During the inactive period of bees, especially during the winter, the bee nest requires heat savings. Ceiling ventilation must be closed. During this period of the year the closure is hung 8. During the winter when the temperature is lowered, the required amount of ventilation can be adjusted by opening the closure 8 from the top down as needed. In this case, fresh air will flow through this opening, but the carbon dioxide will partially dye at the bottom of the chamber as ventilation is through openings 18 and 18 A. During this time, the hive runner is completely closed with a latch and fresh air is fed into the bee socket 8. Partially accumulated carbon dioxide in chamber 2 has a beneficial effect on the heat of this room and the bee nest because it has a higher thermal insulation compared to air.

If there is a need to decarbonise chamber 2 and enhance the supply of fresh air to the bee nest, a second venting option is used: by sliding the closure 8 upwardly, the desired ventilation in the bee nest and chamber 2 can be achieved. the bottom frame 36 of the frame is formed with a slope of 4.5 ° to the running side, which enhances the flow of fresh air into the bee nest,

Ί but the top floor plane 4 is parallel to the horizontal bars of the frames. Above floor 1, a free space of 15 mm is created up to a horizontal bar-36 for the winter bee farm. By creating a slope of the floor, sliding the floor extends the height from the lower horizontal bars 36 to the plane of the floor 1 4. With such a floor solution, the bee winter crop is not swelled in the chamber 2. In addition, carbon dioxide and air are moisture removal into the chamber 2.

Above the sliding floor top plane 4, the inclined running pitch 5 is formed with a slope 6 such that the running height is 8-9 mm and the elevation slope is 10 mm long from the top floor plane. This elevation eliminates the need to make a runway insert that reduces the intended height by 15 mm. Each joint causes heat loss in the bee nest. To lower the recommended hive outdoors on the ground while protecting the chamber 2 from moisture and to thermally insulate the floor space from the outside, the lower part of the floor frame is covered with a thermo-and waterproofing plate 16 and the plane 14A is parallel to the floor plane

3. Under this plate there is an elevation on the running side of the floor and on the opposite side of the floor frame to accommodate a sling for the transport of the hive. The joints of all exterior wall compartments and components of a multi-body hive are slanted outwards, while the two vertical walls, parallel to the lateral edge of the bee cells, form a half-stroke attachment.

In the second embodiment, when the sling floor is not slidable, for example, analogous to the Advanced Anhpycc Russian Hive, the plane 4, the elevation 6 and the semi-tread plane 5 are covered with a thicker polyethylene film up to the vent 18. with a ventilation screen with one edge attached to the edge of the polyethylene film. In this way, ventilation of the bee nest is provided through chamber 2. If necessary, pulling the film slightly out opens the path for the bees to chamber 2, and in the spring, replacing the film with fallen bees against a clean film speeds up the beekeeper's work and eliminates the need to disinfect the floor.

The position of the bee hive container with the runner on the 44 side of the inner space of the container is shown in Fig.4. In this case, the runner is laterally enclosed by floor partitions and slabs of slabs 42 attached to it, and its surface facing the runner with a slope of 33 ° is covered by an organic glass or glass plate roof. Departure of the bees in direction 45 occurs through the floor opening below the floor of the container 40. If the beehive is located in movable containers (Fig. 2; Item 41), the part of the hive run to allow the bees to leave the container may be formed from the vertical wall. In this way, placing the hives in a container in a row along the outer walls and placing each adjacent hive in the opposite direction of the runner reduces the pooling of bees in foreign hives and allows for a larger amount of hives to be placed in the container.

The object of the invention described above is also achieved by extending the ventilation-condensation flow. In the enclosed enclosure 2, which protects the bee nest from rapid cooling, condensation of moist air occurs outside the bee nest. The height of each wall of a multi-hulled hive is greater than its width, while the internal horizontal cross-section of the hull is 0.12 m ² , which concentrates the warm air in the winter bee ball. In the summer heat, the chamber 2 is designed to lower the temperature in the bee nest without widening the runway opening. During transport of the bees, the chamber 2 performs the function of a strong fan and ensures the release of carbon dioxide as well as the exit of the bees from the socket to the ventilated lower part. The chamber 2 has a built-in ventilation system that allows to change the ventilation parameters according to the seasonal temperature changes, the number of bees, etc. The offered multi-body hive can be used both for open-air, container, pavilions, long-distance transportation of gas apiaries. Beekeeping with these hives reduces bee labor and improves the microclimate in the bee nest during both active and passive periods. The high and narrow frames in the multi-body hives are designed to reinforce the wax and plastic artificial cells, facilitating the vertical transition between the bees and the mother, eliminating the need for changing the shells and lining the maternal screen, reducing the number of hives per container or shed at the expense of reunion in foreign hives.

The proposed multi-hulled hive (a total of more than 4,000 different structural elements have been tested in practice in different climatic conditions in Latvia and Ukraine, as well as in northern Russia-Karelia. Transporting this apiary for thousands of km at + 25-50 ° C did not result in any loss of bee colonies. for example, in industrial beekeeping with a large number of beehives, it is not desirable to make the outer frame 22 of the hive feeder and can be replaced by freeing the hive body from the frames with a larger plastic container 31 if the bees are fed at the same time.

Specification of the structural elements shown in the figures:

1. Mobile sling floor;

2. Closed cell under floor 1 with a slope of 4.5 ° of the sub-floor plane 3. This chamber is intended to be extended outside the bee nest by 400 mm to discharge the used air stream by exchanging it with fresh, oxygen-rich air. This airflow can be regulated by an opening closure 8, partially retaining carbon dioxide in the chamber or completely venting the chamber. In addition, the chamber is designed for ventilation without bee outlet or outlet from the socket during the transfer of bees, as well as for ventilation in hot weather for large bee colonies.

3. Subfloor plane.

4. Top floor plane.

5. Running (floor) elevation.

6. Runway elevation slope.

7. Uneven running plane.

8. Adjustable vent opening for bee nest ventilation.

9. Ventilation sieve - running plane - for bees.

10. A Plate for attaching the ventilation sieve.

11. Uneven anti-slip surface of the shutter to prevent the bees from slipping.

12. Grille for adjusting the ventilation direction.

13. A vent vent screen, bent at its upper end approximately 25 mm wide parallel to the plane of the movable floor 3..

14. A Upper plane of chamber 2 floor;

15. Floor frame.

16. A Thermal and waterproofed slab of chamber floor

17. Chamber floor elevation for fastening belt components to belt during transport.

18. Ventilation width of the floor opening.

18. A Front ventilation opening from floor-3 to -14A.

19. Slope created by 4 ° hive components.

20. Plane vertical outer wall plane.

21. Hive housing.

22. Outer frame of the feeder.

23. Hinged roof covering.

24. Roof frame.

25. Roof ventilation screen.

26. Roof ventilation clearance.

26. A Free space bulkhead

27. Thermally insulated adjustable ceiling ventilation plate.

28. Insulated sleeve.

29. Hole to create a vent 30

30. Vent opening.

31. Feeding vessel with floating perforated float.

32. Bee passage to the feeder, as well as passage for the ventilation of the bee nest.

33. Entrance to the feeder.

34. Free body space above the bee nest.

35. Upper frame bar.

36. Bottom bar of frame.

37. Frame vertical bar.

46. The hive housing 21 has a recess for raising the housing (Fig. 1).

41. A T-wire metal profile bar is mounted vertically in the container walls between the slings (Fig. 2).

47. Support for moving floor 1 (Fig. 2A).

48. Power Supply Support (Fig.2A).

49. Frame support to prevent bees from trailing the frames in the hive housing.

50. Bee nest ventilation passage without bee passage in enclosed chamber 2 (Fig. 1).

51. Hinge Component Fastener (Fig.2A and 3A)

52. Hive Body and Frame, Top View (Fig.3A)

53. Transition of the vertical bar of the frame from the thickest thickness of 8 mm to a thickness of 4 mm at the point which coincides with the vertical plane 54 of the artificial cell to secure it (Fig. 3A).

54. Vertical artificial cell (Fig. 3A).

55. In the upper part of the front and rear wall of the housing there is a groove for fixing the frames at a depth of 17 mm (Fig.3A).

38. Container rectangular metal beam (Fig.3).

39. Wooden beam (plank) for floor covering (Fig.3).

40. Container floor (Fig.3).

42. Bee flight boundary wall (Fig.3).

43. Organic glass or glass cover for running inspection (Fig.3).

44. Internal space of the container (Fig.3).

45. Flight direction of bees (Fig. 3)

56. Bee run aperture for bee sting (Fig. 1) in the upper body.

Abstract

The invention refers to beekeeping. The hive offered is characterized by: a ventilation recess 18A connecting a space of bees nest under floor 1 provided with chamber 2 for ventilation and moisture condensation; the said recess is formed beneath the entrance floor and ali over its length and width is provided vvith a removable ventilation net 9; a ventilation damper 8 meant for control of recess 18A is suspended from outside against the said net; the floor of the hive can be shifted and removed after removal of the case and is provided vvith a conic extension, vvhich extends from the internals hive's frame vvall that is located opposite to the floor, as far as the entrance; a podium of the floor suppressed to the upper plan 7 of the floor is formed under the entrance; the floor is thermo- and hydro-isolated. The height of each vvall in the multi-case hive is greater then its vvidth, and the area of the horizontal cross-section of the case is chosen appropriately to the average diameter of the bees' bail in winter time; junctions of constituents of hive's outer vvalls slope outvards; planes 4 and 6 of the floor and partially planets 5 of the entrance is covered by a thick polyethylene film 4A as far as the recess 18A, vvhich ali over its vvidth is covered by the ventilation net 13A that by one side is fastened to an edge of polyethylene film. Arrangement of hives in a displaceable Container of pavilion type is characterized in that entrances of hives are darkened in opposite directions; flying-out of bees is accomplished through recess formed in the floor of the container; entrances sideways above the floor are delimited by partitions, vvhich above entrances are covered by sheets of glass or acrylic plastic forming a roof. Figure annexed (Fig.l) shovvs the lateral section of a multi-case hive inserted into the Container.

Formula of the Invention

Claims (11)

A multi-hulled beehive comprising: one or more hulls; running and running floor; feeding bowl with frame; ceiling covering; narrow or high plastic or wooden frames for fixing artificial wax or plastic cells; vertical and horizontal shingles; roof and floor ventilation screens, in which the bodies, floor and ceiling are made of heat-resistant material and are intended to be placed in a series of transportable containers along external walls and with vertical runners, in order to improve the microclimate in the bee nest and provide hives compliance with traveling industrial and backyard apiculture in a variety of climatic conditions, with the aim of simultaneously reducing the labor intensity of serving bees and increasing the placement of hives in a container or pavilion by reducing the chance of bees gathering in foreign hives, - an adjustable or non-adjustable opening 18 for ventilation, connecting the bee-nest space below the floor 1 to the ventilation and air-condensation chamber 2, extending along the entire length of the inner floor opposite the bee run, extending the ventilation flow in the hive within 400500 mm, then the ventilation in the ventilation chamber 2 is controlled by the chamber closure 8, - a sling floor with a ventilation screen without removable housing, formed by a sliding and removable tapered extension from the inside wall of the floor frame to the runway, where an elevation is created above the floor below the runway and terminates with an uneven running surface plane facing downwards. The bee hive according to claim 1, characterized in that the distance from the vertical outer edge of the housing to the inside of the hive 9 to the plane part of the sieve 9 is within 15-30 mm and the maximum ventilation opening 18 is 10-50 mm, its width above the grid or bottom grid is limited by a wide sieve 25 fixed in the bee passage chamber and, by pulling the grid outside the sieve, the bees can pass into the chamber. 2. A bee hive according to claim 1, characterized in that a vent opening in the width of the floor is provided underneath the running plane of the floor, which has a removable ventilation screen attached to the plane 10A and simultaneously performing the functions of the running plane. hanging closure for adjusting 8 vents 18A from top to bottom or vice versa. 3. The bee hive according to claim 1, characterized in that, with the ventilation opening closed, the bottom floor plane 3 is formed with a slope of 4.5 ° to the running side relative to the lower bar 36 of the frame in the housing and the upper plane being parallel. frames for horizontal bars. The bee hive according to claim 1, characterized in that the elevation above the upper plane of the sliding floor is designed to have a running height of 8-9 mm and a slope of the elevation to the upper plane of the floor 4 of 10 mm. The bee hive according to claim 1, characterized in that the floor chamber 2 is covered by a thermo-and waterproofed plate from the bottom, where its upper plane 14A is parallel to the lower plane 3 of the floor 1. 6. A bee hive according to claim 1, characterized in that high narrow frames for attaching artificial cells of plastic or wax are inserted into the housing of the multi-body hive. 7. The bee hive according to claim 1, characterized in that the height of each wall of the multi-hulled hive is greater than its width, and the inside horizontal cross-sectional area of the housing is 0.12 m ² equal to the diameter of the winter beehive of the average bee family. 8. The bee hive according to claim 1, characterized in that the joints of all components of the hive are formed with an outward inclination, while the joints of the two vertical walls parallel to the side edge of the bee cells are formed as a cam-groove attachment. half a second. 9. The bee hive according to claim 1, characterized in that the hive floor is not slidable, but the top floor plane 4 and the slope 6 of the run lift 5 are partially covered with a thick polyethylene film up to a formed opening 18 30mm wide, the vent opening 18 is covered with a ventilation screen with one edge attached to the edge of the polyethylene film throughout its width. The placement of bee hives according to any one of the preceding claims, in a movable pavilion-type container, characterized in that they are arranged along external walls, preferably adjacent to the hives placed in the opposite directions and the hives arranged inside the room with the runner, bee departure is created through an opening in the floor. 11. The arrangement of bee hives according to any one of claims 1 to 9 in a movable pavilion-type container, characterized in that the bee hives are placed in a container with a runner on the side of the room, the runner being laterally enclosed by partitions and its surface facing the run. created with an inclination of 33 ° is covered with a canopy of glass or glass plate.