RU206973U1 - THERMAL CHAMBER FOR TREATMENT OF BEES FROM THE VARROA MITE - Google Patents

Abstract

The utility model relates to devices for heat treatment of honey bees against Varroa mite. The technical result of the proposed utility model is to increase the effectiveness of treatment of bees from the Varroa mite. The technical result is achieved in a thermal chamber for treating bees from Varroa mite, containing a mesh drum for bees located inside the working part, a thermostat for maintaining a constant temperature, an electric air heater, an element for removing mites, an electric drive for rotating the drum, the inner working part of the chamber is limited by two side walls and a shell having a spiral shape in cross-section, the air supply from the electric heater to the inner working part of the chamber is located between the edges of the spiral surface of the shell located at the maximum and minimum radii of the spiral surface, the electric air heater consists of an aluminum alloy radiator, a posistor as a heat source, fixed on the radiator, and the fan directed to the radiator, located with the provision of air supply from the radiator to the inner working part of the chamber, there is an electronic unit for controlling the operation modes of the chamber, a rotation drive of the mesh drum s From the drive shaft, kinematically connected to the electric motor, on which the mesh drum is supported for rolling, the rolling surface has a protrusion made to ensure the shaking of the mesh drum when rolling on the drive shaft. The electronic unit for controlling the operating modes of the camera can be organized on the basis of a microcontroller and memory for 4 modes. The contact surfaces of the drive shaft with the drum may be rubber coated to provide good adhesion to the drum surface. The side walls can have openings for air outlet. The chamber can contain four rollers, two on each side wall, which are stops when the drum rotates on the drive shaft. 5 ill.

Description

The utility model relates to devices for heat treatment of honey bees against Varroa mite.

There is a known analogue - a heat chamber for treating bees from the Varroa mite - RU193875, 09/25/2019, containing a housing, fixed in it with the possibility of rotation around its axis, a cassette holder for installing a cassette with bees and heat sources, characterized in that it has two heat sources, one of which TI2 is installed along the axis of rotation of the cassette, another heat source TI1 is located in the lower part of the front wall of the housing under the viewing window, and a lamp for illumination and an automatic switch are installed inside the housing; on the side wall outside the case there are a chain transmission closed with a flap and a handle for rotating the cassette, and on the front wall outside the case there are: a switch for halogen lamps, a clock and a heat chamber's work schedule, and the front and back walls are equipped with handles for carrying a heat chamber.

The first disadvantage of the analogue is the lack of an automatic mode of operation of the heat chamber. The drive of the cassette holder is carried out manually, the operating mode is controlled by the operator using a clock and a schedule. The second disadvantage of the analogue is the impossibility of implementing the optimal mode of heating and cooling the chamber, which is required for effective treatment of bees. The analog chamber has a high temperature inertia and does not allow to quickly change the temperature in the entire working volume.

Known analogue - a heat chamber for treating bees from the Varroa mite - RU95461, 03/23/2010, adopted as a prototype, containing a housing made of plywood, inside which is a mesh drum for bees, a thermostat for maintaining a constant temperature, an electric air heater, an element for removing mites, characterized in that it is equipped with an electric drive for rotation of the drum.

The advantage of the prototype in comparison with the analogue is the presence of an electric drive for rotation of the drum.

The disadvantage of the prototype is the low efficiency of treatment of bees from the Varroa mite, due to two factors. The first factor is the impossibility of realizing the optimal mode of heating and cooling the chamber, which is required for effective treatment of bees. The method of treating bees from Varroa mite with temperature shocks in a heat chamber consists in rapid heating and subsequent cooling. At the same time, a key factor for ensuring the effectiveness of the method is a rapid temperature change throughout the chamber volume with strict adherence to the heating and cooling time intervals. These characteristics are important, because only a narrow range of temperature-time conditions leads to the withdrawal of ticks from the normal life and separation from the bees, but does not harm the health of the bees. The chamber and the means of its heating in the analogous device have a high temperature inertia and do not allow to quickly change the temperature in the entire working volume. The second factor limiting the effectiveness of the device is the lack of a means to ensure the timely shaking off of ticks from the bodies of bees.

The technical result of the proposed utility model is to create a device for a heat chamber with increased efficiency compared to analogues in the implementation of the method of treating bees from the Varroa mite.

The technical result is achieved in a thermal chamber for treating bees from Varroa mite, containing a mesh drum for bees located inside the working part, a thermostat for maintaining a constant temperature, an electric air heater, an element for removing mites, an electric drive for rotating the drum, the inner working part of the chamber is limited by two side walls and a shell having a spiral shape in cross-section, the air supply from the electric heater to the inner working part of the chamber is located between the edges of the spiral surface of the shell located at the maximum and minimum radii of the spiral surface, the electric air heater consists of an aluminum alloy radiator, a posistor as a heat source, fixed on the radiator, and a fan directed to the radiator, located with the provision of air supply from the radiator to the inner working part of the chamber, there is an electronic unit for controlling the operation modes of the chamber, a rotation drive of the mesh drum s From the drive shaft, kinematically connected to the electric motor, on which the mesh drum is supported for rolling, the rolling surface has a protrusion made to shake the mesh drum when hitting it during rolling on the drive shaft.

The electronic unit for controlling the operating modes of the camera can be organized on the basis of a microcontroller and memory for 4 programs.

The contact surfaces of the drive shaft with the drum can be polyurethane coated to provide good adhesion to the drum surface.

The side walls can have openings for air outlet.

The chamber can contain four rollers, two on each side wall, which are additional supports for the drum.

Figure 1 shows a cross-section of a heat chamber for the treatment of bees from the Varroa mite across the shell.

Figure 2 shows a cross-section of a heat chamber for treating bees from the Varroa mite along the shell.

Figure 3 shows the shell of a heat chamber for treating bees from the Varroa mite.

Figure 4 shows a heat chamber for treating bees from Varroa mite with an open lid.

Figure 4 shows a cross-section of the drive shaft of a heat chamber for treating bees from Varroa mite in the rolling surface zone.

The thermal chamber for treating bees from Varroa mite contains a mesh drum 2 for bees located inside in the working part 1, as shown in Fig. 1, a thermostat for maintaining a constant temperature, an electric air heater 3, an element for removing mites 4, an electric drum rotation drive, an internal working part 1 of the chamber is bounded by two side walls 5, as shown in Fig. 2, and a shell 6 having a spiral shape in cross-section, as shown in Figs. 1, 3, the air supply from the electric heater 3 to the inner working part 1 of the chamber is located between the edges 7 , 8 of the spiral surface of the shell 6, located at the maximum R and minimum r radii of the spiral surface of the shell 6, as shown in Fig. 3, the electric air heater 3 consists of a radiator 9 made of aluminum alloy, a posistor 10 as a heat source fixed on the radiator 9, and fan 11 directed to the radiator 9, located with the provision of air supply from the radiator 9 to the internal working part 1 of the camera, there is an electronic unit 12 for controlling the operating modes of the camera, as shown in Fig. 4, the drive for rotation of the mesh drum consists of a drive shaft 13, shown in Fig. 2, kinematically connected to an electric motor (in Fig. not shown), on which the mesh drum 2 is supported with the possibility of rolling, the rolling surface 14 has a protrusion 15, as shown in Fig. 5, made to ensure the shaking of the mesh drum 2 when rolling on the drive shaft 13. The electronic unit 12 for controlling the operating modes of the chamber can be organized on the basis of a microcontroller and memory for 4 programs. The contact surfaces 14 of the drive shaft 13 with the drum 2 may be coated with a polyurethane coating to provide good adhesion to the surface of the drum 2. The side walls 5 may have openings 16 for air outlet, as shown in FIGS. 2, 4.

Let us consider an example of a specific implementation of a heat chamber for treating bees from the Varroa mite. The mesh drum 2 for bees has the shape of a cylinder and consists of two steel rings to which the mesh is welded. The lower part of the drum is deaf, and the upper removable one is mounted on two pins and has two types of entrance and exit (for loading and unloading bees). Side walls 5, front 17 and rear 18 walls and cover frame 19 are made of plywood. Shell 6 is made of sheet aluminum alloy. Due to the fact that the shell 6 has a spiral shape in cross-section, and the air supply from the electric heater 3 to the inner working part 1 of the chamber is located between the edges 7, 8 of the spiral surface of the shell 6, an air flow of a given temperature constantly passes through the volume of the inner working part 1 and at By changing the heating temperature of radiators 9, the temperature in the entire volume of the working part 1 changes as quickly as possible. The side walls 5 have openings 16 for air outlet, which ensures a constant renewal of the air of a given temperature inside the working part 1 of the chamber and the removal of excess moisture during processing. This is important to ensure accurate temperature control inside the working part 1 of the chamber and to achieve a technical result. At the bottom of the shell there is a slot 4, which is an element for removing the tongs.

The electric air heater 3 consists of a radiator 9 made of aluminum alloy, placed over the entire width of the chamber. As a source of heat used posistors 10 - thermistors with a positive temperature coefficient of resistance. Posistor heaters allow for a forced heating mode to a predetermined temperature and allow you to effectively maintain the temperature of the chamber with significant changes in the ambient temperature and preset heating and cooling modes, that is, they have a low inertia of temperature changes. They are fixed on the radiator 9, due to which a fast transfer of the temperature of the posistor 10 to the radiator and the distribution of air of a given temperature with the help of three fans fixed there is ensured 11. The PID regulator (English abbreviation - PID) is used as an electronic unit 12 for controlling the camera operation modes. , which carries out proportional, integrating and differential control. It is connected with a temperature sensor inside the working part 1 of the chamber and 10 posistors and is a thermostat to maintain a constant temperature. The electronic unit 12 has a memory for 4 processing programs. Four programs are needed to select a regime for a certain weight of the bee colony. If there is only one program, there is a possibility that the regime will not fit the weight of the bee colony. Then, in the best case, there will be no proper effect from the treatment, in the worst case, the bees will die, since the heating temperature and holding time will be higher than necessary for a given family weight.

The drive shaft 13 is made of steel pipe and is driven by a geared motor. The contact surfaces 14 of the drive shaft 13 with the drum 2 have a polyurethane coating that provides good adhesion to the surface of the drum 2. The rolling surface 14 has a projection 15 made of the same polyurethane by casting directly onto the shaft. Thanks to the polyurethane coating, the drum 2 rotates despite the presence of the projection 15. Without the polyurethane coating, the drum 2 can slide relative to the shaft 13. In another embodiment, the projection 15 is located on the rolling surface of the drum 2.

There are four rollers 20, as shown in Fig. 1, two on each wall 5, which are additional supports when the drum 2 rotates on the shaft 13. Due to the presence of rollers 20, it is possible to drive the drum 2 from the shaft 13 located below and to shake the drum 2 when hitting the projection 15. The rollers 20 keep the drum 2 from displacement relative to the shaft 13, but do not restrict its movement vertically when shaken. In the lower part of the chamber under the slot 4 there is a tray 21 for collecting mites fallen from bees.

Let's consider an example of the use of a heat chamber for treating bees from the Varroa mite. The lid 19 of the chamber is opened, as shown in Fig. 4, the drum for bees 2 is taken out and bees infected with Varroa mite are placed in it. After that, the drum is installed in the chamber on the drive shaft 13. One of the camera operation programs is started by selecting it on the interface of the electronic unit 12. The drum 2 begins to rotate from the drive shaft 13. The electronic unit 12 gives a signal to supply voltage to the posistors 10, they heat up gradually following the program mode up to a temperature of 48 degrees, transferring heat to the radiator 9, the fans 11 distribute the heated air inside the working part 1 of the chamber, the air comes out of the side openings 16. The mites lose more than 10% of moisture due to heating, the mite's legs dry and stop sticking to the surface of the bee, as a result, the mites are separated from the body of the bees, some of them die. When hitting the projection 15, the rotating drum 2 is shaken, due to which the mites fall off the body of the bees more efficiently and through the slot 4 fall onto the tray 21. After reaching the maximum allowable temperature in the chamber according to the processing program, the temperature of the thyristor according to the specified mode of the electronic unit 12 decreases. Due to the mutual arrangement of the posistors, the radiator 9, the fans 11 and the spiral shape of the shell 6 of the chamber, the temperature in the entire working part 1 of the chamber decreases rapidly, thereby eliminating the negative effect of a short-term increase in temperature on the bees. The cycle repeats after 3 seconds. The temperature ranges and time intervals are performed by the electronic unit 12, which ensures precise adherence to the temperature regime and achieves the technical result.

Claims (5)

1. Thermal chamber for treating bees from Varroa mite, containing a mesh drum for bees located inside in the working part, a thermostat for maintaining a constant temperature, an electric air heater, an element for removing mites, an electric drive for rotating the drum, characterized in that the inner working part of the chamber is limited by two lateral walls and a shell having a spiral shape in cross section, the air supply from the electric heater to the inner working part of the chamber is located between the edges of the spiral surface of the shell located at the maximum and minimum radii of the spiral surface, the electric air heater consists of an aluminum alloy radiator, a posistor as a heat source , fixed on the radiator, and a fan directed to the radiator, located with the provision of air supply from the radiator to the inner working part of the chamber, there is an electronic unit for controlling the modes of operation of the chamber, the rotation drive of the mesh drum consists of the water shaft, kinematically connected to the electric motor, on which the mesh drum is supported for rolling, the rolling surface has a protrusion made to ensure the shaking of the mesh drum when hitting it during rolling on the drive shaft. 2. Thermal chamber for treating bees from Varroa mite according to claim 1, characterized in that the electronic unit for controlling the operating modes of the chamber is organized on the basis of a microcontroller with memory for 4 programs. 3. The thermal chamber for treating bees against Varroa mite according to claim 1, characterized in that the contact surfaces of the drive shaft with the drum have a polyurethane coating that provides good adhesion to the drum surface. 4. A thermal chamber for treating bees against Varroa mite according to claim 1, characterized in that the side walls have openings for air outlet. 5. Thermal chamber for treating bees from Varroa mite, characterized in that there are four rollers, two on each side wall, which are additional supports for the drum.

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