RU2111655C1 - Bee family heating apparatus - Google Patents

Abstract

FIELD: heating equipment. SUBSTANCE: heating apparatus has power transformer, AC stabilizer, current transformers, heating members and beehive temperature regulators. Number of heating members corresponds to the number of beehives. AC stabilizer has current sensor, rectifier unit with filter, control unit, protection unit, controllable power regulator and current setter. Beehive temperature regulator has temperature sensor, temperature setter, amplifying circuit, power unit and shunting element. Apparatus is adapted for heating plurality of bee families by means of low-current circuit connected to secondary circuit of power transformer (one per 1 apiary) for breakage or short-circuit protection. Construction of heaters provides automatic setting of required current and voltage parameters. EFFECT: increased efficiency in setting required bee family keeping conditions. 4 dwg

Description

 The invention relates to the field of beekeeping and may find application in individual and collective apiaries.

 Known devices for regulating the temperature of the air in the hive (SU, A1, 1579486, class A 01 K 47/00, 1990). All of these devices are mainly connected in parallel to the transformer. With a large number of connections and with a low electrical safety voltage (12 V), the currents increase significantly. Therefore, the disadvantages of such devices for controlling the temperature of the air in the hive are a large current with a low electrically safe (12 V) power supply voltage and with a large number of connected heating elements per transformer, large dimensions of the transformer, a large cross section of the supply wires (with 20 - 35 connected heaters in the apiary, the diameter lead copper wires is 8 - 10 mm). If you increase the voltage to 220 V on the heaters while maintaining the same power, then the current decreases, but then electrical safety is violated.

 In order not to use expensive transformers, beekeepers use a serial connection of heating elements. Then the current through the heating elements will decrease, you can use small diameter lead wires used in the mains for power supply, and a small transformer. This circuit also has disadvantages. In the event of a break in the series circuit, all heating elements in the hives are de-energized. With a large number of connected loads, a high electro-hazardous voltage arises at the rupture site. When connecting N loads, it is necessary to monitor the correct voltage setting, careless connection of the unsuitable suitable voltage can lead to failure of the heating elements, overheating of the bee colonies and even their death.

 Small-sized low-power transformers can be used for each heating element. But since these transformers are located near the hive or in the hive, electrical safety is violated (220 V is supplied to the hive) and fire hazard.

 In order to eliminate these shortcomings, a device for heating bee colonies (SU, A1, 1625460, class A 01 K 47/00, 1991) containing a power transformer, a temperature controller, a heating element, the input of the power transformer is connected to the mains, an alternating current stabilizer is introduced current, the first and second power inputs of which are connected to the first and second output of the first secondary winding of the power transformer, the first and second outputs of the second secondary winding of the power transformer are connected to the third and fourth power inputs of the stabilizer For alternating current, the first power output of the AC stabilizer is connected to the first input of the first hive current transformer, the second input of which is connected to the first input of the first heating element of the first hive, the second input of the heating element of the first hive is connected to the first input of the second hive current transformer, the second input of which is connected with the first input of the second heating element of the second hive, the second input of the second heating element is connected to the first input of the nth current transformer of the Nth hive, the second input which is connected to the first input of the nth heating element of the Nth hive, the second input of the nth heating element of the Nth hive is connected to the second output of the AC stabilizer, the inputs of the heating elements by the number of hives are connected to the first and second inputs of the hive temperature controllers , the third and fourth inputs of the hive temperature controllers are connected to the first and second outputs of the current transformers.

 In FIG. 1 is a structural diagram of a device for heating bee colonies: a power transformer - 1, an AC stabilizer - 2, current transformers by the number of hives - 3, heating elements by the number of hives - 4, hive temperature controllers - 5, hives - 6, the first output of the first the secondary winding of the power transformer is 7, the second output of the first secondary winding of the power transformer is 8, the first output of the second secondary winding of the power transformer is 9, the second output of the second secondary winding of the power transformer is 10, the first output is stabilized and the current is 11, the second output of the current stabilizer is 12, the terminal for connecting the beehive regulator 13, the first terminal for connecting the heating element is 14, the second terminal for connecting the heating element is 15, the first output of the current transformer is 16, the second output of the current transformer is 17 .

 In FIG. Figure 2 shows the structural diagram of the current stabilizer: current sensor - 18, rectifier unit with filter - 19, control unit - 20, protection unit - 21, controllable power regulator - 22, current regulator - 23, power input bus of current sensor - 24, first power the output bus of the current sensor is 25, the second output bus of the current sensor is 26, the third output bus of the current sensor is 27, the first input of the rectifier block is 28, the second input of the rectifier block is 29, the output bus of the rectifier is 30, the output bus is 31, the output control unit bus - 32, output of the controlled power regulator - 33, s current regulator sludge bus 34.

 In FIG. Figure 3 shows the structural diagram of the hive temperature controller: temperature sensor - 35, temperature setter - 36, amplification scheme - 37, power supply unit - 38, shunt element 39, first output bus of the power supply unit - 40, second output bus of the power supply unit - 41, input of the circuit amplification - 42, control bus - 43, the first power input of the shunt element - 44, the second power input of the shunt element - 45.

 In FIG. 4 shows the design of the heating element.

 Structurally, the heating element consists (see Fig. 4) of two plates made of insulating material (glasses). Insulating gaskets 1 are laid on the first plate, a spiral 2 is laid between the insulating gaskets, the leads of which are led to the edge 3. The entire surface is covered with glue, a second plate is placed on the glued part.

 Structurally, the power transformer 1, the current stabilizer 2 are performed in one housing (Fig. 1). On the front panel, a voltage indicator, a current indicator, a current regulator regulator, mains fuses, and terminals for connecting an electric line with heating elements can be installed.

 Structurally, the beehive temperature controller 6 and current transformer 3 are made in one housing, on the front panel are installed terminals 13, 14, 15 and the knob of the temperature controller regulator - 35. The temperature sensor 34 is remote, displayed by a separate cable, placed by beekeepers.

 The heating element 4 and the hive temperature controller 5 are located at the bottom of the hive. The heating element 4 is connected to the terminals 14, 15, and the terminals 13, 15 are connected to a two-wire power line connected to a socket installed on the outside of the hive at the bottom of the hive.

A device for heating bee colonies works as follows. When the device is de-energized, there is no voltage at the outputs 11, 12 (Fig. 1) of the current stabilizer 2. After turning on the power supply, the mains voltage of 220 V is supplied to the power transformer 1, which is necessary for galvanic isolation from the mains in order to prevent phase voltage from entering the secondary network. From the first secondary winding, the power output AC voltage through the outputs 7, 8 is supplied to the first and second power inputs of the current stabilizer 2. From the second secondary winding through the outputs 9, 10, the voltage is supplied to power the current stabilizer 2. If the outputs 11, 12 of the current stabilizer the line with heating elements 4 and hive temperature controllers 5 is not connected, there is no hazardous voltage on them. When connecting the maximum number of heating elements 4, the number of which is determined by the power of the power transformer 1 and the power of the current stabilizer 2, at the outputs 11, 12 of the current stabilizer 2 there is a maximum voltage U _max . The optimum power of the heating elements is 12 - 40 watts. When the supply voltage of the heating element 4 U _pit = 12 V and power P = 18 W, the current through the heating element 4 is I _load = 1.5 A. The voltage of 12 V on one heater is safe for the beekeeper. In order to have a minimum current with a large number of connected heating elements 4, their series connection is used.

The current stabilizer 2 (Fig. 2) contains a current sensor 18, made in the form of a transformer, on the secondary winding of which a voltage is generated proportional to the current passing through the primary winding, which enters the current stabilizer through the power input bus of the current sensor 24. Formed voltage through the third the output bus of the current sensor 27 is fed to the first input of the control unit 20, which is fed through the output bus of the rectifier 30 from the rectifier unit with a filter 19. An alternating supply voltage is supplied to the unit For a filter 19 through the first and second inputs of the rectifier unit 28, 29 from the second secondary winding of the power transformer 1. Using a current regulator 23, the beekeeper can set the value of the passing current through the heating elements 4, which allows you to adjust the power on the heating elements from 12 to 40 W . The power voltage through the first power output bus of the current sensor 25 is supplied to the first power input of the controlled power controller 22. The control action generated by the current sensor 18 and the current master 23, through the output bus of the control unit 32 is supplied to the control input of the controlled power controller 22. The power voltage, stabilized by current, through the output of the controlled power regulator 33 and through the power bus of the current stabilizer 34 is supplied to the first and second outputs of the current stabilizer 11, 12. If a line is connected to revatelnymi hive elements and temperature regulators 5, the circuit current flows. The current stabilizer 2 maintains the current at the same level I _nom = const, regardless of the number of connected heating elements: from one to n - heating elements. The voltage at the outputs 10, 11 of the current stabilizer 2 varies from U _min = 12 B (one heating element 5) to U _max = n • 12 B, where n is the number of heating elements.

For the implementation of temperature thermoregulation in each hive there are hive temperature controllers 5 (Fig. 3). Using a temperature setter 36, the beekeeper sets the heating temperature of each hive. Information about the temperature coming from the temperature sensor 35, and information about the set temperature set by the master temperature sensor 36, enters through the input 42 to the amplification circuit 37. The power of the temperature regulator 5 is supplied from the power supply 38, the alternating voltage is supplied from the outputs 16, 17 secondary winding of current transformer 3. Since a stable current flows through current transformer 3, a stable alternating voltage is present at the outputs of the secondary winding 16, 17. A constant voltage from the power supply unit 38 feeds the electronic circuit of the beehive temperature controller 5 through the output buses 40, 41. When the set temperature is reached, the amplification circuit 37 gives a control action, which is transmitted through the control bus 43 to the control input of the shunt element 39. The power inputs 44, 45 are switched . When the shunt element 39 is open, the supply voltage of the heating element 4 (12 B) was present at the first and second terminals 14, 15, this heating element 4 is heated. When the set temperature is reached, the heating element is switched off by switching the current through the shunt element 39, while the serial circuit of the heating elements 4 is not turned off (Fig. 1), and the power supply to this heating element 4 is stopped. Since the heating element 4 was switched off by shunt, the voltage rises on all other series-connected heating elements 4. The decrease in the resistance of the series circuit causes an increase in current, it is detected by the current sensor 18. The control unit 20 gives a control action through the bus 32 to the controlled power regulator 22, which causes a decrease in the power voltage at the outputs 11, 12 of the current stabilizer. This leads to the establishment of the initial I _nom current set at the maximum number of heating elements (n = n _max ). After operation of the hive temperature regulators 5 of all hives 6 in a series circuit, a situation close to short circuit (short circuit) may occur. In reality, short circuit can be eliminated, since there is ballast resistance equal to the resistance of the lead wires and power shunt elements 39 (thyristors, transistors). If relays are used as shunt elements 39, then the ballast resistance corresponds to the resistance of the lead wires. Protection against short circuit in the circuit of the current stabilizer 2 occurs automatically, since as the number of connected heating elements 4 decreases, the supply voltage at the outputs 11, 12 of the current stabilizer automatically decreases. In this case, U _kz = U _shunt + U _prov , where U _shunt is the total voltage drop across the shunt elements (state "closed circuit") and U _prov is the voltage drop across the supply wires. In the event of a break in the serial circuit of the heating elements 4 from the current sensor 18, information is sent to the protection unit 21 via the bus 26, where a signal is generated that is transmitted via the bus 31 to the control unit 20. Here, information on the blocking of the controlled power regulator 22 is also generated on the bus 32. the outputs 11, 12 of the current stabilizer 2 power hazardous voltage is almost completely removed. This protection is very important, because at the point of breaking the serial circuit when the loads are fully connected, voltage that can be life-threatening can occur. At the outputs 11, 12 of the current stabilizer 2 there remains a small standby voltage, which is not dangerous for the beekeeper, and when the break is closed, the current stabilizer 2 sets the initial set current I _nom .

 Thus, the proposed device for heating bee colonies allows the use of a low-current circuit in the secondary circuit of the power transformer (one per apiary), which allows the use of a small-sized power transformer, and wire connections used for wiring with a small (up to 1 mm) diameter, reduce the number of wires in the apiary. In the event of a break or short circuit, a protection is provided that turns off the current stabilizer 2. After eliminating the break, the current stabilizer 2 is automatically set to the specified current, which determines the installed power of the heating elements 4. The heating elements can be connected when the supply voltage is connected. The presence of a power transformer 1 eliminates the hazardous phase voltage. All this leads to the convenient use in practical beekeeping of the proposed device for heating bee colonies (high electrical safety, comparable to the parallel connection of low-voltage heaters; low fire hazard, the possibility of use with a long connection and a minimum of control).

Claims (1)

 A device for heating bee colonies containing a power transformer, a temperature controller, a heating element, the input of the power transformer is connected to the mains, characterized in that an AC stabilizer is introduced, the first and second power inputs of which are connected to the first and second outputs of the first secondary winding of the power transformer, the first and second outputs of the second secondary winding of the power transformer are connected to the third and fourth power inputs of the AC stabilizer, the first power output the AC tabulator is connected to the first input of the first hive current transformer, the second input of which is connected to the first input of the first heating element of the first hive, the second input of the first hive heating element is connected to the first input of the second hive current transformer, the second input of which is connected to the first input of the second heating element the second hive, the second input of the second heating element is connected to the first input of the n-hive current n-transformer, the second input of which is connected to the first n-heating input of the N-hive element, the second input of the N-hive N-heating element is connected to the second output of the AC stabilizer, the inputs of the heating elements are connected by the number of hives to the first and second inputs of the hive temperature controllers, the third and fourth inputs of the hive temperature controllers are connected to the first and second outputs of current transformers.

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