RU2199857C1 - Beehouse (versions) and method of year-round bee keeping in beehouse - Google Patents

Abstract

FIELD: apiculture. SUBSTANCE: beehouse has spacer arranged between nest casing and bottom casing and equipped with casing retainers, stopper, members for regulating gap between cover and end of part arranged under cover. Base is positioned between part arranged under cover and nest casing and is made in the form of plate provided with honeycomb frame mounting members and with members for retaining nest casing and part arranged under cover. Cover is provided with vent slots for communicating space of part arranged under cover with atmosphere. Through holes are formed in beehouse ceiling and bottom casing. Spring-summer beehouse is characterized in that it has additional cylindrical nest casing comprising support, plate for separating nest casing from bottom casing, spacer positioned between nest casing and bottom casing and equipped with members for retaining said casings and with members for regulating gap between cover and end of part arranged under cover. Each of bases is made in the form of plate equipped with honeycomb frame mounting members and with members for retaining nest casings and part arranged under cover. Cover is provided with vent slots for communicating space in the vicinity of part arranged under cover and atmosphere. Through holes are formed in spring-summer beehouse ceiling and bottom casing. Method involves providing rotation of nest casings depending on season of the year: reducing beehouse volume for autumn- winter period by removing nest casing, which had been top part during spring-summer period of the year, and placing required number of honeycomb frames containing feed in remaining casing; setting vent opening sizes for autumn- summer period; upon termination of spring-summer period, lifting nest casing with wintered bee family therein and locating it in top part; providing optimal air-heat mode by means of gap regulator. EFFECT: increased efficiency by providing bee keeping conditions allowing biology to be realized to maximum extent regardless of climatic-landscape zone conditions. 61 cl, 9 dwg

Description

 The invention relates to the development of beehive designs and methods for optimal year-round keeping of bee families (bees) in them, which make it possible to approximate the living conditions of bees in them to maximize the implementation of bee biology regardless of climatic landscape zones.

 There are various designs of hives that can be divided into vertical and horizontal.

 Due to their multi-case vertical hives make it possible to maintain large bee colonies or several families year-round with little or no interference in the life of the beekeeper.

 Vertical designs of beehives in a round form, a method for assembling a beehive and a method for keeping bees year-round in it are described in RF patent 2169462, cl. A 01 K 47/00, 2000 with the location of the frames in the radius and alternating them with shortened frames consisting of two buildings, with a stand for the hive and the ability to move the bees from top to bottom, which is taken as a prototype according to the claimed designs, the method of assembly and a way of keeping bees in them year-round. The hive is easy to manufacture, but for a number of reasons, it does not for all parameters satisfy the hygienic requirements for keeping bees.

 The objective of the proposed invention is the development of designs of beehives and methods for optimal year-round keeping of bees in them, allowing approximating the optimal living conditions of bees in them, ensuring the maximum possible implementation of bee biology regardless of climatic landscape zones.

 In terms of the design, the task is solved by the fact that the hive for the autumn-winter keeping of the bee family includes cylindrical roof liners, nesting and bottom bodies, the walls of which are made of three layers, a ceiling, a cover made in the form of a three-layer structure, honeycomb frames mounted on a lodgement in the nesting box the housing with the main and additional slots, according to the invention is equipped with a spacer installed between the nest and bottom housings and made with the elements of their fixation, a plug and size adjusters for there is a gap between the cover and the end face of the roof cover, the lodgement is installed between the roof cover and the socket housing and is made in the form of a plate equipped with elements for installing honeycomb frames and fixing the socket body and the roof cover, the cover is made with ventilation slots for communicating the volume of the roof cover with the atmosphere in the ceiling to communicate the volume of the socket through holes in the housing with the volume of the armpit and in the bottom body for communicating the volume of the bottom body with the atmosphere, while the plug is installed on the ceiling and is made with by overlapping holes in the ceiling.

 The following particular essential features contribute to the solution of the problem.

 The lodgement element for installing honeycomb frames is made in the form of a quadrangular hole, which is made rectangular with a ratio of its sides within 1 ... 1.5.

 The lodgement element for installing honeycomb frames is made in the form of five quadrangular holes that are rectangular, four holes are placed around the perimeter of the 5th hole, each of the 4 holes is opposite the corresponding side of the 5th hole and parallel to it with its larger side, the length ratio the greater side to the length of the smaller side of each of the 4 rectangular holes is within 3-6, and the ratio of the length of the larger side of each of the 4 holes to the length of the side of the 5th hole is within 0.3 ... 0.9 .

 The lodgement element for fixing the nesting body and the roof liner is made in the form of two annular ribs, one rib is placed on the lodgement on the side of the auricle, the second rib is on the side of the nesting housing.

 The lodgement element for fixing the armpit and the nest housing is made in the form of three annular ribs, one rib is placed on the lodgement on the side of the arm, the second and third ribs are on the side of the nest housing, while the third rib is made in the form of an annular bend towards the nest housing along the outer contour lodgement.

 The spacer element for fixing the nest and bottom bodies is made in the form of two annular ribs, one rib is placed on the connecting spacer on the side of the nest body, the second rib is on the side of the bottom body.

 The spacer element for fixing the nest and bottom bodies is made in the form of three annular ribs, one rib is placed on the connecting spacer from the side of the nest body, the second and third ribs are on the side of the bottom body, while the third rib is made in the form of an annular bend towards the bottom body the outer contour of the spacer.

 The ceiling rests on the lodgement of the nesting case, the plug is made in the form of a round plate and covers 10 ... 99% of the holes in the ceiling.

 The plug is made of wood with a thickness of 2. ..11 mm from sheets of veneer with a thickness of 0.5 ... 1.0 mm with the connection of the layers with glue.

 The shells of the armpit and the nest body are made in the shape of a circular cylinder, and the bottom body is made in the form of a circular cylindrical glass.

The inner diameter D _{1 of the} armwort, nest and bottom bodies is found from the ratio (A ₁ -50) / B = 1.3 ... 1.6, where B is the width of the honeycomb frame in mm.

 The width of the honeycomb frame is within B = (0.9 ... 1.2) 400 mm.

The height H _{1 of the} armworm is found from the ratio H ₁ = (0.2 ... 0.4) B. The height H _{2 of the} female housing is found from the ratio of H ₂ = (1.2 ... 1.7) V. The height of the internal volume H _{3 of the} bottom body is found from the ratio of H ₃ = (0.7 ... 1.0) V.

The thickness C _{1 of the} cover, the bottom of the bottom shell, the walls of the nesting and bottom shells is found from the ratio C ₁ = 70 + (0.05 ... 0.2) B.

где F=B₁h₁ - площадь поперечного сечения основного летка; π=3,14159.In the nesting cases, the main notch is made in the form of a rectangular slot, while the width B _{1 of the} slot is oriented across the nesting housing and is determined from the relation B ₁ = (20 ... 21.7) h ₁ , where h ₁ = 11.9 .. .12.1 mm - the gap height of the main notch, the additional notch is made of circular cross section, while the diameter D _{2 of the} additional notch is determined from the ratio

where F = B ₁ h ₁ - the cross-sectional area of the main notch; π = 3.14159.

 The ceiling is made in the form of a round plate with a thickness of 2 ... 11 mm from veneer sheets of wood with a thickness of 0.5 ... 1.0 mm with the connection of layers with glue.

 The ceiling is made of non-resinous pine wood.

Grooves of width B ₂ are made in the lid in the inner outer layer, which is determined from the relation B ₂ = (16 ... 17) h ₂ , where h ₂ = 2.0 ... 3.1 mm is the height of the groove.

 In the lid, the outer polymer layer is made in the form of a cylindrical glass with a supporting flange, and the layer facing the inside of the hive is made in the form of a round plate, which are connected, and a foam composition is placed between them.

 The layers of the shells, facing the inside of the hive, of the underwing and of the bottom body, are made with a thickness of 9.. .11 mm of wooden planks connected in the form of a drum, ensuring overlapping joints with a joint in a spike or paw and on casein glue.

 The layers of the shells, facing the inside of the hive, the roof cover and the bottom body, are 2 ... 11 mm thick from sheets of wood veneer with a thickness of 0.5 ... 1.0 mm and the layers are glued together.

 The layer of the shell facing the inside of the hive, of the nest housing, is made with a thickness of 9.. . 11 mm from wooden plates connected in the form of a drum, with overlapping joints with a joint in a spike or paw and on casein glue.

 The layer of the shell facing the inside of the hive, of the nest housing, is made with a thickness of 2.. .11 mm from veneer sheets of wood with a thickness of 0.5 ... 1.0 mm with the connection of layers with glue.

As a sheet of polymer material is used polyvinyl chloride with a thickness of 0.2. . .3 mm with a bending strength of at least 500 kgf / cm ² with a temperature of application from -40 to 80 ^o C.

Polyfoam is used with a bulk weight of 40 ... 60 kg / m ³ , with a breaking stress during compression of at least 0.2 ... 0.5 MPa and with a thermal conductivity of not more than 0.029 W / (m • K), with a temperature of application from -40 to 80 ^o C and with water absorption of not more than 2%.

 Cell frames are used in two sizes - frames and half frames.

 Parallel honeycomb frames are installed in the socket housing with a pitch between them, which is within 36 ... 39 mm.

 The lodgement is made of environmentally friendly plastic.

 The openings in the bottom body of the side wall are inclined so that the passage of air from the outside to the bottom of the bottom body is carried out upward.

 A beehive for the spring-summer keeping of the bee family, including cylindrical roof liner, nesting and bottom bodies, the walls of which are made of three layers, a ceiling, a cover made in the form of a three-layer structure, honeycomb frames mounted on a lodgement in the nesting case with the main and additional slots, according to the invention equipped with an additional cylindrical nest housing and an additional lodgement, a dividing plate that separates the volume of the nest and bottom housings, a spacer installed between the nests ov and bottom cases and made with the elements of their fixation and regulators of the size of the gap between the cover and the end face of the roof cover, the lodgement is installed between the cover and the socket housing, and an additional lodgement is installed between the socket bodies, each lodgement is made in the form of a plate equipped with elements for installing honeycomb frames and fixation nesting cases and the roof cover, the cover is made with ventilation slots for communicating the volume of the roof cover with the atmosphere, in the ceiling for communicating the volume of the socket housing with the volume of through holes in the bottom housing for through the volume of the bottom housing with the atmosphere through holes are made, while the separation plate is mounted on the spacer.

 The following particular essential features contribute to the solution of the problem.

 The separation plate is made in the form of a round flat plate with perforation.

 The separation plate is made in the form of a round concave plate with perforation. The separation plate may be made of wood or a polymeric material.

 In terms of the year-round method of keeping bees, the problem is solved in that in the method of year-round keeping of a bee family, comprising forming a bee club according to the seasons of the year in a two-hive hive with vertically arranged hulls and ensuring free access of bees to honeycombs simultaneously in different nesting cases, according to the invention they use beehives with cylindrical-shaped nesting cases, which are placed on the bottom, while nesting cases are rotated depending on the season of the year, for In the winter season, the nest volume is reduced by removing the nest housing from the hive, which was the upper one in the spring and summer, and installing the required number of honeycomb frames with feed in the remaining housing, and the cavity is made between the lower ends of the honeycomb frames and the bottom of the bottom housing by removing the separation plates, a cap is installed on the ceiling, while the size of the holes for the autumn-winter period is established in the ceiling, having previously calculated the required total area, at the end of the above nests the casing with the overwintered family is lifted up, and a second nesting casing with the same arrangement of the honeycomb frames is installed under the bottom casing as in the first and communicating with the first, the cavity between the bottom of the casing and the ends of the honeycombs is eliminated by installing a spacer plate on the spacer, a cap it is removed from the ceiling, and between the lid and the end face of the roof cover, the gap size is set using the gap regulator for the spring-summer period, taking into account the required total area, providing optimal ny air-heat mode hive.

 The following particular essential features of the method of year-round maintenance of the bee family contribute to the solution of the problem.

Slots form in the ceiling, the total area S of which is determined as a function of the temperature T ^o K of the outdoor air and the internal volume of the hive in the form S = T ^o VA, where T ^o is the temperature average for the coldest five-day period in the autumn-winter period and average for the most a hot month in the spring-summer period in kelvins, V is the volume of the hive in mm ³ ; A = (2 ... 3) • 10 ^-8 1 / (mm • K) - coefficient adopted for the autumn-winter maintenance of the bee family; A = (11 ... 13) 10 ^-8 1 / (mm • K) - for the spring-summer period of keeping bees.

 Private essential features of the invention are presented in figure 1 ... 9.

 Figure 1 shows the hive for the autumn-winter maintenance of the bee family; in FIG. 2 - the constituent elements of the hive for the autumn-winter maintenance of the bee family; in FIG. 3 - lodgement (top view); figure 4 is a section AA of figure 3; in FIG. 5 - spacer (top view); figure 6 is a cross section of the explosive in figure 5; Fig.7 is a beehive for the spring-summer keeping of the bee family; on Fig - the constituent elements of the hive for the spring-summer maintenance of the bee family; figure 9 is a sequence of rotation of the hive bodies with year-round maintenance of the bee family.

 2. The hive for the autumn-winter keeping of bees (FIGS. 1, 2) contains the nesting case I, the honeycomb frame II, the ceiling III, the roof lid IV, the cover V, the bottom case VI, the lodgement VII, the spacer VIII, the cap IX. The ceiling III is made in the form of a round plate (figure 2) with through holes 1. The bottom body VI is made in the form of a cylindrical glass with a bottom 2 and with through holes 3 in the cylindrical surface. The nest building I is made with the main 4 and additional 5 years.

 Cover V (Fig. 2), roof cover IV, ceiling III, socket I and bottom VI of the housing are made in the form of separate modules of circular cross section, successively installed with ends facing each other, while the lodgement VII is installed between the ends of the roof of IV and socket housing I, and between the ends of the nest and bottom bodies - spacer VIII. Ceiling III is installed on lodgement VII, and cap IX is installed on the ceiling. The cover V is made in the form of a three-layer plate with radial channels from the side of the armwind IV (radial channels are not shown in the figures). Awning IV and socket housing I are made in the form of circular cylindrical pipes. Cell frames II are placed on the cradle VII, while between the lower ends of the honeycomb frames and the bottom 2 of the bottom body VI there is a cavity A. The holes 3 of the bottom body VI communicate its inner cavity A (Fig. 1) with the atmosphere. The hole 3 in the wall of the bottom shell VI is made with an inclination so that the passage of air from the outside to the bottom of the bottom shell is upward.

 The specified slope prevents atmospheric precipitation from getting inside the hive. At the same time, in the autumn-winter period, fresh air enters through the opening 3 in the bottom hull, which is mixed in the cavity A of the bottom hull with the warm air of the hive and thereby provides fresh air to the hive. Air escapes through the ceiling openings, not closed by a plug, into the volume of the roof cover and further through the grooves in the cover into the atmosphere. The dimensions of the grooves in the lid, the openings in the ceiling, and the openings in the bottom housing provide temperature and humidity conditions in accordance with the biological characteristics of the bee club in the autumn-winter period.

 Lodgement VII (Fig. 3) is made in the form of a plate equipped with elements for installing the honeycomb frames and fixing the nesting housing and the underbody.

 The lodgement element for installing the honeycomb frames (Figs. 3, 4) is made in the form of five quadrangular holes that are rectangular, four holes K are placed around the perimeter of the 5th hole I. Each hole K is located opposite the corresponding side of the hole And parallel to it with its larger side .

To install the honeycomb frames (Fig. 3, 4) in the hole And the ratio of its sides is within E ₁ / E ₂ = 1 ... 1,5, where one of the sides of the hole And, for example E ₁ , corresponds to the width of the honeycomb frame. For effective use of the internal volume of the nest housing along the perimeter of the hole And there are holes K for installing cellular half frames. In accordance with a circular cross-section, the ratio of the length of the larger side to the length of the smaller side of the hole K is in the range of E ₄ / E ₃ = 3-6, and the ratio of the length of the larger side of the hole K to the length of the side of the hole And is in the range of E ₃ / E ₁ = 0.3. . . 0.9. The found size ratios of the holes in the tool tray allow using the standard sizes of the honeycomb frames and half frames.

 The lodgement is equipped with elements for fixing the nest housing and the armpit, made in the form of two annular ribs 6 and 7. The rib 6 is placed on the lodgement from the side of the armpit, the rib 7 is located on the side of the nesting housing and prevent mutual displacement of the armpit and the nesting housing under the transverse load . At the same time, the ribs form a labyrinth at the junction, which prevents the passage of air into the hive. The third rib 8 is made in the form of an annular bend along the outer contour of the lodgement towards the nest housing, which also contributes to the development of the labyrinth and protects the internal volume of the nest housing from atmospheric precipitation.

 The spacer (figure 5, 6) is designed to connect and fix the nest and bottom bodies. The fixing element of the spacer is made in the form of three annular ribs 9, 10, 11. The rib 9 is placed on the spacer from the side of the nesting body, the ribs 10 and 11 from the side of the bottom body, while the rib 11 is made in the form of an annular bend towards the bottom body on the outside spacer contour. The ribs on the spacer create a labyrinth at the junction of the nest and bottom bodies, prevent atmospheric precipitation from entering the hive and create a mechanical bond that prevents the bodies from moving relative to each other.

To ensure the possibility of placing a sufficient food base for the autumn-winter period, the following sizes (Fig. 2) of the hive were selected from the experience of breeding bees: the inner diameter of D ₁ (mm) of the wing, nest and bottom of the hull is found from the ratio (D ₁ -50) / V = 1.3 ... 1.6, where B is the width of the honeycomb frame in mm; the width of the honeycomb frame is within B = (0.9 ... 1.2) 400 mm; the height of H _{1 of the} armpit is found from the relation H ₁ = (0.2 ... 0.4) B; the height H _{2 of the} female housing is found from the ratio of H ₂ = (1.2 ... 1.7) V; the height of the internal volume H _{3 of the} bottom shell is found from the ratio of H ₃ = (0.7 ... 1.0) V.

To ensure the temperature regime inside the hive from the experience of breeding bees in the autumn-winter period, the thickness C _{1 of the} lid, the bottom of the bottom body, the walls of the auriculum, the nest and bottom bodies is found from the ratio C ₁ = 70+ (0.05 ... 0.2) B.

 The outer layer of the three-layer wall structure is made of sheet polymer material in the lid, undercoat, nest and bottom bodies, the layer facing the inside of the hive is made of wood, and the intermediate layer between them is made of a foam composition. The layer of the three-layer wall structure, facing the inside of the hive, is made of wood, as it brings the bees' habitat closer to their natural biology. The outer layer, facing the inside of the hive, of the three-layer shell, is allowed to be made of sheet polymer material in the underwort and the bottom body, since in these volumes the bees do not directly contact these surfaces.

 In the lid, undergrowth, nest and bottom cases, the layer facing the inside of the hive, three-layer shell can be made of 9 ... 11 mm thick from wooden plates connected in the form of a drum, with overlapping joints with a joint in a spike or paw and on casein glue. The thickness of the layers is determined from the technological conditions.

 In the lid, undercoat, nest and bottom cases, the layer facing the inside of the hive can be made of 2 ... 11 mm thick from sheets of wood veneer with a thickness of 0.5 ... 1.0 mm with the connection of the layers with glue. The thickness values are selected from manufacturing technology.

According to the results of technological testing and experience in breeding bees, polyvinyl chloride with a thickness of 0.2 is used as a sheet polymer material. . . 3 mm with a bending strength of at least 500 kgf / cm ² with a temperature of application from -40 to 80 ^o C.

To ensure the temperature and humidity conditions inside the hive according to the results of calculations, technological testing and experience in breeding bees, foam is used with a bulk weight of 40 ... 60 kg / m ³ , with a breaking stress during compression of at least 0.2 ... 0.5 MPa and with a coefficient of thermal conductivity of not more than 0.029 W / (m, K), with a temperature of application from -40 to 80 ^o C and with water absorption of not more than 2%.

 The cylindrical shape of the nest and bottom bodies brings bees closer to their natural conditions in hollows. The experience of observing the state of a hive of rectangular cross-section shows that mold congestion often forms in the inner corner zones, which adversely affects the condition of bees, which can be explained by the presence of stagnant zones in the corner areas during natural ventilation of the hive and which is absent in hollows and hives of a circular cross section.

 The hive for the spring-summer keeping of the bee family (Fig. 7/9, 8) contains the nest building I, the honeycomb frame II, the ceiling III, the roof lid IV, the cover V, the bottom building VI, the lodgement VII, the spacer VIII, the second nest building X, second lodgement XI and dividing plate XII. The ceiling III is made in the form of a round plate (Fig. 8) with through holes 1. The bottom case VI is made in the form of a cylindrical cup with a bottom 2 and with through holes 3 in a cylindrical surface. Nest housings I and X are made with the main 4 and additional 5 years.

 Cover V (Fig. 8), roof cover IV, ceiling III, socket I, second socket X and bottom VI of the housing are made in the form of separate modules of circular cross-section, successively installed with ends facing each other, while between the ends of the roof of IV and socket housing X the lodgement VII is installed, between the ends of the nest building I and the nest building X, the lodgement XI is installed, and the spacer VIII is installed between the ends of the nest and bottom bodies. Ceiling III is installed on lodgement VII, and dividing plate XII is installed on spacer VIII. The cover V is made in the form of a three-layer plate with radial channels from the side of the armwind IV (radial channels are not shown in the figures). Awning IV and socket housings I and X are made in the form of circular cylindrical pipes. Cell frames II are placed on lodges VII and XI, while a separation plate XII is installed between the lower ends of the honeycomb frames and the cavity A of the bottom housing VI on spacer VIII.

 The construction of the lodgement, spacers, roof cover, cover, nest bodies and bottom body are given in the description of the autumn-winter hive.

 The separation plate is made in the form of a round flat plate with perforation. The separation plate does not allow the bees to penetrate into the volume of the bottom body for its unplanned development with honeycombs, and perforation allows sifting of garbage and parasites to the bottom of the bottom body.

 The separation plate may be made in the form of a round concave plate with perforation. The presence of curvature (concave) in the separation plate allows to increase its rigidity. The separation plate may be made of wood or a polymeric material.

 The main 4 and additional 5 slots are made on each nest building I and X, the additional let is located above the main let and its center is located on a straight line, which is the axis of symmetry of the main let. The effectiveness of the additional taphole and its position were proved experimentally during the period of intensive honey collection.

 To improve ventilation, lid adjusters are installed on the lid between the lid and the end face of the roof cover f, which can be placed between the cover and the end face of the roof cover (not shown in the figures).

A method for year-round keeping of the bee colony in the hive is shown in FIG. 9; FIG. Figure 9 shows the rotation sequence of the hive buildings with year-round maintenance of the bee family. The hive for the spring-summer keeping of the bee family in Fig. 9 is designated "V-L-1" and "V-L-2", and the hive for the autumn-winter keeping of the bee family "OZ-1" and "OZ -2 " Initially, the club of the bee family is located in Building X in the “V-L-1” hive, which is explained by the biology of the bees during their natural habitat in the hollow, in which building, breeding and accumulation of honey occur from the top of the hollow. As in the hollow, the bees in the hive descend in the building X as the honeycombs are built up and freely move into the building I. During the spring-summer period, the bees completely build up and fill both buildings I and X of the B-L-1 hive with honey. To keep the bees in the autumn-winter period in the hive "VL-1" remove the building X with the accumulated honey for its processing. The lid V and the armwind IV from the case X are moved to the case I. The separation plate is removed from the spacer, so that a cavity A is formed between the bottom of the bottom case and the bottom end of the frames, in which the bee club is placed in full accordance with their biology (as in hollows). On the ceiling III (figure 2) with holes, a plug IX is installed, which covers such a number of holes that in the autumn-winter period it provides normal temperature and humidity conditions for the bee club. As a result of this conversion, the "OZ-1" hive was obtained for the autumn-winter keeping of a bee family in it. During the autumn-winter period, the club of bees, as well as in the hollow, as honey is eaten, moves up hull I and by the end of wintering (the beginning of spring-summer keeping) it appears at the upper point of hull I of the hive "OZ-1". For spring-summer keeping, the nest buildings I and X are rotated. The nest building I with the dezresimy family of bees is moved (rotate) up, and the case X, taken earlier with honey for processing, is installed down. Separate the cavity A of the bottom body by installing a separation plate on the spacer. As a result of this conversion, a hive "V-L-2" is formed for the spring-summer keeping of the bee family. As a result of the rotation of the nest buildings, the bee family ended up at the top of the spring-summer hive V-L-2 as well as the spring-summer hive V-L-1. The spring-summer hive of VL-2 bees are completely built up and filled with honey from both hulls I and X. Then, to keep the bees in the autumn-winter period, hull I with hived honey is removed in the Hive “VL-2” for processing. The lid V and the roof cover IV from the housing I are rearranged onto the housing X. The separation plate is removed from the spacer, due to which a cavity A is formed between the bottom of the bottom housing and the lower end of the frames, in which the bee club is placed in full accordance with their biology (as in hollows). On the ceiling III (figure 2) with holes, a plug IX is installed, which covers such a number of holes that in the autumn-winter period it provides normal temperature and humidity conditions for the bee club. As a result of this re-equipment, the "OZ-2" hive was obtained for the autumn-winter keeping of a bee family in it. Thus, the cycle can be repeated and on the basis of the proposed designs of the hives (figure 1, 2, 7, 8,) year-round content of bees is achieved in them. At the same time, in the hive ceiling, the size of the slits (holes) of their required total area F is established, which ensures the optimal air-heat regime of the hive, which is defined as a function of the temperature T ^o K of the outdoor air and the internal volume of the hive in the form F = T ^o VA, where T ^o - temperature, average for the coldest five-day period in the autumn-winter period and average for the hottest month in the spring-summer period in kelvins, V - volume of the hive in mm ³ , A = (2 ... 3) 10 ^-8 1 / ( mm • K) - coefficient adopted for the autumn-winter maintenance of the bee family; A = (11 ... 13) 10 ^-8 1 / (mm • K) - for the spring-summer period of keeping bees.

 From the submitted application material it follows that a cylindrical hive is more preferable, because corresponds to natural hives in the form of hollows, and the goal of the present invention is achieved - year-round maintenance of bee colonies in cylindrical hives is provided.

Claims (61)

 1. Beehive for the fall-winter keeping of the bee family, including cylindrical roof liner, nesting and bottom bodies, the walls of which are made of three layers, a ceiling, a cover made in the form of a three-layer structure, honeycomb frames mounted on a lodgement in the nesting case with the main and additional doors, characterized in that the beehive is equipped with a spacer installed between the nest and bottom bodies and made with elements for their fixation, a plug and gap size regulators between the cover and the end face of the roof cover, bed t is installed between the roof cover and the socket housing and is made in the form of a plate equipped with elements for installing honeycomb frames and fixing the socket housing and the roof cover, the cover is made with ventilation slots for communicating the volume of the roof cover with the atmosphere in the ceiling to communicate the volume of the socket body with the volume of the roof cover and Through holes for communicating the volume of the bottom body with the atmosphere are made through holes, while the ceiling is supported by a lodgement, and the plug is installed on the ceiling and is made with the possibility of overlapping holes in the ceiling.  2. A beehive according to claim 1, characterized in that the lodgement element for installing honeycomb frames is made in the form of a quadrangular hole.  3. The hive according to claim 2, characterized in that the quadrangular hole of the lodgement element for installing honeycomb frames is rectangular, while the aspect ratio of the rectangular hole in the lodgement is in the range of 1-1.5.  4. The hive according to claim 1, characterized in that the lodgement element for installing the honeycomb frames is made in the form of five quadrangular holes.  5. The hive according to claim 4, characterized in that the five quadrangular holes of the cradle element for installing honeycomb frames are rectangular, four rectangular holes are placed around the perimeter of the 5th rectangular hole, each of four rectangular holes for installing honeycomb frames is located opposite the corresponding side of the 5th rectangular hole and parallel to it with its larger side, and the ratio of the length of the larger side to the length of the smaller side of each of the four rectangular holes located n the perimeter of the 5th rectangular hole, is within 3-6, the ratio of the length of the larger side of each of the four rectangular holes of the lodgement element for installing honeycomb frames to the length of the side of the 5th rectangular hole, around which four rectangular holes are located, is within 0 3-0.9.  6. A beehive according to claim 1, characterized in that the lodgement element for fixing the nest body and the roof cover is made in the form of two annular ribs, one rib is placed on the lodgement from the side of the roof cover, the second rib from the side of the socket housing.  7. The hive according to claim 6, characterized in that the second rib from the side of the nesting housing is made in the form of an annular bend along the outer contour of the lodgement towards the nesting housing.  8. Beehive according to claim 1, characterized in that the lodgement element for fixing the roof cover and the nest housing is made in the form of three annular ribs, one rib is placed on the lodgement from the side of the roof cover, the second and third ribs are from the side of the nest housing, while the third rib made in the form of an annular bend towards the nesting housing along the outer contour of the tool tray.  9. The hive according to claim 1, characterized in that the spacer element for fixing the nest and bottom bodies is made in the form of two annular ribs, one rib is placed on the connecting spacer from the side of the nest body, the second rib is from the bottom body.  10. The hive according to claim 9, characterized in that the second rib from the side of the bottom body is made in the form of an annular bend towards the bottom body along the outer contour of the spacer.  11. The hive according to claim 1, characterized in that the spacer element for fixing the nest and bottom bodies is made in the form of three annular ribs, one rib is placed on the connecting spacer on the side of the nest body, the second and third ribs are on the side of the bottom body, the third rib is made in the form of an annular bend towards the bottom body along the outer contour of the spacer.  12. The hive according to claim 1, characterized in that the plug is made in the form of a round plate of wood with a thickness of 2.. . 11 mm, from veneer sheets of wood with a thickness of 0.5. . . 1.0 mm with the connection of the layers with glue and overlaps 10.. . 99% of the holes in the ceiling.  13. The hive according to claim 1, characterized in that the bottom body is made in the form of a circular cylindrical glass. 14. The beehive according to claim 13, characterized in that the shells of the armpit and the nest housing are made in the shape of a circular cylinder, and the inner diameter D _{1 of the} armwort, the nest and bottom bodies is found from the ratio (D ₁ -50) / B = 1.3. . . 1.6, where B = (0.9... 1.2) 400 is the width of the honeycomb frame in mm. 15. The hive according to claim 14, characterized in that the height H _{1 of the} armworm is found from the ratio H ₁ = (0.2.. 0.4) B, the height H _{2 of the} nesting housing is found from the ratio H ₂ = (1,2 ... 1.7) B, the height H _{3 of the} internal volume of the bottom body is found from the ratio H ₃ = (0.7... 1.0) B. 16. The hive according to claim 14, characterized in that the thickness C _{1 of the} lid, the bottom of the bottom shell, the walls of the auriculum, the nest and bottom shells is found from the ratio C ₁ = 70+ (0.05... 0.2) B. 17. The hive according to claim 1, characterized in that in the nest housing the main let is made in the form of a rectangular slot, while the width B _{of the} slot is oriented across the nest housing and is determined from the relation B ₁ = (20... 21.7) h ₁ , where h ₁ = 11.9. . . 12.1 mm is the height of the slit of the main notch, and the additional notch is made of circular cross-section, while the diameter D _{2 of the} additional notch is determined from the ratio

where F = B ₁ h ₁ - the cross-sectional area of the main notch;
π = 3.14159.  18. The hive according to claim 1, characterized in that the ceiling is made in the form of a round plate with a thickness of 2.. . 11 mm from veneer sheets of wood with a thickness of 0.5. . . 1.0 mm with bonding layers of glue. 19. The hive according to claim 1, characterized in that in the lid in the layer of the three-layer wall facing the inside of the hive, ventilation grooves are made of width B ₂ , determined from the relation B ₂ = (16... 17) h ₂ , where h ₂ = 2.0. . . 3.1 mm - the height of the ventilation groove.  20. The hive according to any one of paragraphs. 1 and 19, characterized in that in the lid the outer polymer layer of the three-layer wall is made in the form of a cylindrical glass with a support flange, the layer facing the inside of the hive is made of a round plate, the layers are connected, and a foam composition is placed between them.  21. The hive according to claim 1, characterized in that in the roof cover and bottom body the layer of the three-layer shell facing the inside of the hive is 9.. . 11 mm from wooden plates connected in the form of a drum, with overlapping joints with a joint in a spike or paw and on casein glue.  22. The hive according to claim 1, characterized in that in the roof cover and bottom body the layer of the three-layer shell facing the inside of the hive is 2.. . 11 mm from veneer sheets of wood with a thickness of 0.5. . . 1.0 mm with bonding layers of glue.  23. The hive according to claim 1, characterized in that in the nesting housing the layer of the three-layer shell facing the inside of the hive is 9.. . 11 mm from wooden plates connected in the form of a drum, with overlapping joints with a joint in a spike or paw and on casein glue.  24. The hive according to claim 1, characterized in that in the nesting housing the layer of the three-layer shell facing the inside of the hive is 2.. . 11 mm from veneer sheets of wood with a thickness of 0.5. . . 1.0 mm with bonding layers of glue.  25. A beehive according to claim 20, characterized in that polyvinyl chloride with a thickness of 0.2 is used as the polymeric material. . . 3 mm.  26. The hive according to claim 1, characterized in that the honeycomb frames are used in two types of sizes - frames and half frames.  27. The hive according to claim 1, characterized in that the parallel honeycomb frames are installed in the socket housing with a pitch between them, which is within 36.. . 39 mm.  28. The hive according to claim 1, characterized in that the lodgement is made of environmentally friendly plastic.  29. A beehive according to claim 1, characterized in that the openings in the bottom body of the hole in the side wall are sloped so that the passage of air from the outside to the bottom of the body is upward.  30. A beehive for the spring-summer keeping of the bee family, including cylindrical roof liner, nesting and bottom bodies, the walls of which are made of three layers, a ceiling, a cover made in the form of a three-layer structure, honeycomb frames mounted on a lodgement in the nesting case with main and additional summers, characterized in that the hive is equipped with an additional cylindrical nest housing and an additional lodgement, a dividing plate separating the volume of the nest and bottom bodies, a spacer installed between in the nest and bottom cases and made with elements for their fixation and regulators of the size of the gap between the cover and the end face of the roof cover, the lodgement is installed between the cover and the nest body, and an additional lodgement is installed between the nest bodies, each lodgement is made in the form of a plate equipped with elements for installing cellular frames and fixation of nest bodies and the roof cover, the cover is made with ventilation slots for communicating the volume of the roof with the atmosphere in the ceiling for communicating the volume of the socket body Through-holes are made with a mustache with the volume of the armpit and in the bottom body for communicating the volume of the bottom body with the atmosphere, while the ceiling is supported by a lodgement located between the ends of the roof cover and the socket body, and the separation plate is mounted on the spacer.  31. A beehive according to claim 30, characterized in that the lodgement element for installing honeycomb frames is made in the form of a quadrangular hole.  32. The hive according to claim 31, characterized in that the quadrangular hole of the tool tray for installing honeycomb frames is rectangular, while the aspect ratio of the rectangular hole is within 1.. . 1,5.  33. A beehive according to claim 30 or 31, characterized in that the lodgement element for installing honeycomb frames is made in the form of five quadrangular holes.  34. The hive according to claim 33, wherein the five quadrangular holes of the lodgement element for installing honeycombs are rectangular, four rectangular holes of the lodgement element for installing honeycombs are placed around the perimeter of the 5th rectangular hole, each of four rectangular holes being located opposite the corresponding side of the fifth rectangular hole and parallel to it with its larger side, and the ratio of the length of the larger side to the length of the smaller side of each of the four rectangular holes The holes located around the perimeter of the 5th rectangular hole are within 3.. . 6, the ratio of the length of the larger side of each of the four rectangular holes of the tool tray for installing honeycomb frames to the length of the side of the 5th rectangular hole is within 0.3. . . 0.9.  35. A beehive according to claim 30, characterized in that the lodgement element for fixing the nest housing and the roof cover is made in the form of two annular ribs, one rib is placed on the lodgement from the side of the roof cover, the second rib from the side of the socket housing.  36. The hive according to claim 35, characterized in that the second rib from the side of the nest housing is made in the form of an annular bend along the outer contour of the lodgement towards the nest housing.  37. The hive according to claim 30, characterized in that the lodgement element for fixing the roof cover and the nest housing is made in the form of three annular ribs, one rib is placed on the lodgement from the side of the roof cover, the second and third ribs from the side of the nest housing, while the third rib made in the form of an annular bend along the outer contour of the lodgement towards the nest housing.  38. The hive according to claim 30, characterized in that the spacer element for fixing the nest and bottom bodies is made in the form of two annular ribs, one rib is placed on the connecting spacer on the side of the nest body, the second rib is on the side of the bottom body.  39. The hive according to claim 38, characterized in that the second rib from the side of the bottom body is made in the form of an annular bend along the outer contour of the spacer towards the bottom body.  40. The hive according to claim 30, characterized in that the spacer element for fixing the nest and bottom bodies is made in the form of three annular ribs, one rib is placed on the connecting spacer on the side of the nest body, the second and third ribs are on the side of the bottom body, the third rib is made in the form of an annular bend along the outer contour of the spacer towards the bottom body.  41. A beehive according to claim 30, characterized in that the bottom body is made in the form of a circular cylindrical glass. 42. A beehive according to claim 30, characterized in that the shells of the roof cover and the nest bodies are made in the shape of a circular cylinder, and the inner diameter D _{1 of the} roof cover, the socket and bottom bodies is found from the ratio (D ₁ -50) / B = 1.3. . . 1.6, where B = (0.9... 1.1) 400 is the width of the honeycomb frame in mm. 43. A beehive according to claim 42, characterized in that the height H _{1 of the} armpit is found from the ratio H ₁ = (0.2.. 0.4) B, the height H _{2 of the} nesting housing is found from the ratio H ₂ = (1.2 ... 1.7) B, the height of the internal volume H _{3 of the} bottom shell is found from the ratio of H ₃ = (0.7... 1.0) B. 44. The hive according to claim 42, characterized in that the thickness C _{1 of the} lid, the bottom of the bottom body, the walls of the nesting and bottom bodies is found from the ratio C ₁ = 70+ (0.05.. 0.2) V. 45. The hive according to claim 30, characterized in that in the nesting cases the main let is made in the form of a rectangular slit, while the width of the ₁ slot is oriented across the nesting housing and is determined from the relation B ₁ = (20... 21.7) h ₁ , where h ₁ = 11.9. . . 12.1 mm - the height of the slit of the main notch, while the additional notch is made of circular cross section, while the diameter D _{2 of the} additional notch is determined from the ratio

where F = B ₁ h ₁ - the cross-sectional area of the main notch;
π = 3.14159.  46. The hive according to claim 30, characterized in that the ceiling is made in the form of a round plate 2. thick. . 11 mm from veneer sheets of wood with a thickness of 0.5. . . 1.0 mm with bonding layers of glue.  47. The hive according to any one of paragraphs. 30 and 46, characterized in that the ceiling is made of non-resinous pine wood. 48. The hive according to claim 30, characterized in that in the lid in the layer of the three-layer wall facing the inside of the hive, ventilation grooves are made of width B ₂ , determined from the relation B ₂ = (16.. 17) h ₂ , where h ₂ = 2.0. . . 3.1 mm - the height of the ventilation groove.  49. A beehive according to claim 30, characterized in that in the underwing, bottom and in the nesting bodies, a layer of a three-layer shell facing the inside of the hive is made of thickness 2.. . 11 mm from veneer sheets of wood with a thickness of 0.5. . . 1,0 mm with the connection of layers with glue or from a sheet of polymeric material.  50. A beehive according to claim 49, characterized in that a polyvinyl chloride of 0.2 thickness is used as a sheet polymer material. . . 2 mm.  51. The hive according to claim 30, characterized in that the honeycomb frames are used in two types of sizes - frames and half frames.  52. A beehive according to claim 30, characterized in that the parallel honeycomb frames are installed in the socket housing with a pitch between them, which is within 36.. . 39 mm.  53. The hive according to claim 30, characterized in that the lodgement is made of environmentally friendly plastic.  54. A beehive according to claim 30, characterized in that the openings in the bottom body of the hole in the side wall are sloped so that the passage of air from the outside to the bottom of the body is upward.  55. A beehive according to claim 30, characterized in that the dividing plate between the bottom and nesting bodies is made round.  56. A beehive according to claim 30 or 55, characterized in that the separation plate is made with perforation.  57. The hive according to claim 30 or 55, characterized in that the separation plate is concave.  58. A beehive according to claim 30 or 55, characterized in that the dividing plate is made of wood.  59. The hive according to claim 30 or 55, characterized in that the separation plate is made of a polymeric material.  60. A method for keeping the bee colony year-round, including forming a bee club according to the seasons of the year in a two-hive hive with vertical hulls and ensuring free access of bees to honeycomb frames simultaneously in different nesting hulls, characterized in that they use hives with nested hulls of cylindrical shape, which placed on the bottom, while the rotation of the nest buildings is carried out depending on the season, for the autumn-winter period, the volume of the nest is reduced by removing the nest housing from the hive, the cat in the spring and summer, it was the upper one, and the required number of honeycomb frames with feed was installed in the remaining casing, and a cavity was made between the lower ends of the honeycomb frames and the bottom of the bottom body by removing the separation plate, a plug was installed on the ceiling, and the size of the holes was set in the ceiling for the autumn-winter period, having previously calculated the required total area, at the end of the above-mentioned period, the nesting building with the wintered family is raised up, and under it on the bottom building pour the second nest housing with the same arrangement of honeycomb frames as in the first, and communicate with the first, eliminate the cavity between the bottom of the bottom housing and the ends of the honeycomb frames by installing a spacer plate on the spacer, remove the plug from the ceiling, and set the size between the lid and the end face of the roof cover the gap with the help of the gap regulator for the spring-summer period, taking into account the required total area, providing the optimal air-heat regime of the hive. 61. The method of keeping the bee colony year-round according to claim 60, characterized in that gaps are formed in the ceiling, the total area S of which is defined as a function of the temperature T ^o K of the outdoor air and the internal volume of the hive in the form S = T ^o VA, where T ^o - temperature average for the coldest five-day period in the autumn-winter period and average for the hottest month in the spring-summer period in degrees Kelvin; V is the volume of the hive in mm ³ ; A = (2... 3) 10 ^-8 1 / (mm • K) - coefficient adopted for the autumn-winter maintenance of the bee family; A = (11.. 13) 10 ^-8 1 (mm • K) - for the spring-summer period of keeping bees.

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