RU2727119C1 - System for adaptive stabilization of wind rotor rotation speed - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: invention relates to wind-power engineering, namely, to systems for prevention of uncontrolled acceleration of Darier windrotor under strong winds. System comprises a wind rotor generator, a non-magnetic rotary current conducting disc, an electromagnetic unit, controller with preset reference value of frequency or with preset threshold value of voltage, comparator. Comparator is connected to phases of the generator and to the controller. Comparator is configured to analyse frequency or voltage value of signal coming from generator. Controller is configured to switch by means of switching voltage switches to the electromagnetic unit when the value of the input voltage exceeds the threshold voltage value or when deviating from the reference frequency value. Electromagnetic unit is made in the form of a multi-winding electromagnetic unit located rigidly relative to the wind rotor, and its pole piece is placed with a gap < 1mm to the plane connected to the wind rotor by a rotating non-magnetic current-conducting disc. Electromagnetic unit is made in the form of separate electromagnets, uniformly distributed along circumference of non-magnetic current-conducting disc.EFFECT: number of electromagnets is less by one than number of phases of generator, and are made so that each next electromagnet is connected at saturation of previous electromagnet and further growth of wind turbine rotation frequency.4 cl, 6 dwg

Description

Technical field

The invention relates to wind energy, in particular to systems for preventing the uncontrolled acceleration of the Darrieus wind rotor in strong winds

State of the art

There is a known method for regulating the speed of rotation of the wind rotor (Patent WO 2009/035363 A1, 2009) When the speed of rotation of the shaft of the wind generator exceeds the calculated value, an active load will be connected, which will lead to braking of the rotor and further, depending on the readings of the sensor of the rotation speed of the generator rotor, the power of the active load is corrected in one direction or another.

The disadvantages of this method include the use of a battery of switched heating elements (TEN) as an active load, therefore, most of the generated energy is dissipated in space in the form of heat, significantly reducing the overall efficiency of the wind generator.

There is also a known method for regulating the speed of rotation of the wind rotor (RF patent No. 2188335, 2001), which consists in ensuring the limitation of the number of revolutions of the vertical-axial wind wheel in a wide range of speeds of the incoming flow, is achieved due to the fact that in the vertical-axial wind wheel containing a vertical a shaft with traverses, at the ends of the traverses vertical profiled blades are installed, on the outer surface of which there are flaps hinged on the blades, and the flap control mechanism, according to the invention, the flaps are located in the tail part of the blade, the trailing edge of the pressed flap coincides with the trailing edge of the blade, and the mechanism flap control consists of a lever rigidly connected to the flap, a spring that is connected to the lever and enclosed in a cage located inside the blade, and an adjusting screw for pre-compression of the spring.

The disadvantages of this method include the technological complication of manufacturing the blade and ensuring the reliability of control in difficult climatic conditions, as well as the impossibility of using the method with curved blades.

The essence of the invention

The object of the claimed invention is to prevent uncontrolled spinning of the wind rotor in strong winds without interrupting the generation of electricity.

The technical result of the claimed invention is to limit the rotational speed of the wind rotor at 300 rpm in the entire wind range.

The technical result of the claimed invention is achieved due to the fact that the system of adaptive stabilization of the speed of rotation of the wind rotor contains: a non-magnetic rotating conductive disk associated with the wind rotor, an electromagnetic unit, a controller with a given reference frequency value or with a given threshold voltage value, a comparator connected to the phases of the wind rotor generator and with a controller, and configured to analyze the value of the frequency or voltage of the signal input from the generator of the wind rotor, wherein the controller is configured to switch by means of switching switches the voltage to the electromagnetic unit when the input voltage exceeds the threshold voltage or deviates from the reference frequency value.

In the particular case of the implementation of the claimed technical solution, the electromagnetic unit is made in the form of a multi-winding electromagnetic unit, located motionlessly relative to the wind rotor, and its pole piece is placed with a gap <1 mm to the plane connected to the wind rotor by a rotating non-magnetic conductive disk.

In the particular case of the implementation of the claimed technical solution, the multi-winding electromagnetic unit is wound on a soft magnetic core with high saturation induction.

In the particular case of the implementation of the claimed technical solution, the electromagnetic unit is made in the form of separate electromagnets, evenly distributed around the circumference of the non-magnetic conductive disk, and the number of electromagnets is less by one than the number of phases of the generator, and are made in such a way that each subsequent electromagnet is connected when the previous electromagnet is saturated and further an increase in the rotation frequency of the wind rotor.

Brief Description of Drawings

Details, features, and advantages of the present invention follow from the following description of embodiments of the claimed technical solution using the drawings, which show:

FIG. 1 is a functional diagram of an adaptive system for stabilizing the rotation speed of a wind rotor with a frequency comparator and an electromagnetic unit made in the form of a multiwinding electromagnetic unit;

FIG. 2 is a functional diagram of an adaptive system for stabilizing the rotation speed of a wind rotor with a frequency comparator and an electromagnetic unit made in the form of separate electromagnets;

FIG. 3 - multi-winding DC electromagnet;

FIG. 4 - the relative position of the non-magnetic conductive disk and electromagnets:

FIG. 5 is a functional diagram of an adaptive system for stabilizing the rotation speed of a wind rotor with a threshold comparator (voltage) and an electromagnetic unit made in the form of a multi-winding electromagnetic unit

FIG. 6 is a functional diagram of an adaptive system for stabilizing the speed of rotation of a wind rotor with a threshold comparator (voltage) and an electromagnetic unit made in the form of separate electromagnets.

In the figures, the following positions are indicated by numbers:

1 - generator; 2 - controller; 3 - standard frequency comparator; 4 - switching keys; 5 - electromagnetic unit; 6 - multiphase rectifier; 7 - non-magnetic conductive rotating disk of the wind rotor; 8 - core; 9 - electromagnet windings.

Disclosure of invention

The problem is solved by the fact that in order to prevent the uncontrolled acceleration of the wind rotor, the effect of braking is used, a rotating non-magnetic conducting disk in a magnetic field caused by Foucault currents.

The system of adaptive stabilization of the rotation speed of the wind rotor contains a generator, a non-magnetic conductive rotating disk (7) of the wind rotor, a standard comparator (3), one input of which is connected to the phases of the generator (1), and the other input is connected to the controller (2). The controller (2), in turn, is also connected to the phases of the generator (1). The electromagnetic unit (5) is connected to the phases of the generator (1) through the switching keys (4). The polyphase rectifier unit (6) is connected directly to the phases of the generator, and the constant voltage from the output is supplied to the standard charger, which provides charging the battery and powering the inverter of the wind generator.

In an embodiment of the claimed system of adaptive stabilization of the wind rotor speed, a frequency comparator (3) is used, one input of which is supplied with a signal of one of the phases of the generator (1), and the other input is supplied with a reference frequency set by the controller (2).

In an embodiment of the claimed system of adaptive stabilization of the rotational speed of the wind rotor due to the direct dependence of the output voltage on the rotational speed, instead of a frequency comparator, a threshold comparator (voltage) is used. 5, Fig. 6. Contains a standard threshold comparator (voltage) 3, one input of which is supplied with a signal of one of the generator phases (1), and the other input is supplied with a reference voltage set by the controller (2). The error signal from the output of the comparator is analyzed by the controller (2) and when the value of the input voltage exceeds the reference voltage, it gives signals to control the switching keys (4) that switch the voltage to the multi-winding electromagnetic unit EM 5 (Fig. 5), or separate electromagnets EM (5 ) (Fig. 6).

The error signal from the output of the comparator (3) is analyzed by the controller (2) and, when the frequency of the input signal exceeds the reference frequency, it sends signals to control the switching keys (4) that switch the voltage to the electromagnetic unit EM (5).

The electromagnetic unit (5) in the embodiment of the claimed technical solution is made in the form of a multi-winding electromagnetic unit (5), which is wound on a soft magnetic core (8) with a high saturation induction to obtain a smooth increase in the magnetic flux intensity with increasing supply voltage from the generator in the entire speed range rotation. The multi-winding electromagnetic unit (5) is stationary relative to the wind rotor, and its pole piece is located with a gap <1 mm to the plane connected to the wind rotor by a rotating non-magnetic conductive disk (7) (Fig. 4), since the smaller the distance between the pole piece of the electromagnetic unit (5) and the conductive surface of the disk (7), the less the loss of the magnetic field for scattering in space and the greater the strength of the Foucault currents in the non-magnetic disk (7) and, accordingly, the power of the braking torque.

The electromagnetic unit (5) in the embodiment of the claimed technical solution is made in the form of separate electromagnets made of electrical steel (Fig. 2). The number of electromagnets is one less than the number of phases of the generator (1). Electromagnets are evenly spaced around the circumference above the non-magnetic conductive disc (7). The first of the electromagnets is activated when the speed is first exceeded over the reference value. Each subsequent electromagnet is connected at saturation of the previous electromagnet and a further increase in the rotational speed of the wind rotor (Fig. 6).

The proposed solution works as follows.

At a speed of up to 300 rpm. The generator works as usual, but when this value is exceeded, the frequency exceeds the threshold of the comparator (3) and the controller (2) switches one of the windings of the polyphase generator (1) to power the first winding of the EM electromagnet (Fig. 1a).

In this case, during the interaction of a constant magnetic field of an electromagnet and a rotating nonmagnetic conductive disk (7), eddy currents (Foucault currents) arise, directed so that the magnetic field they create counteracts the change in the external magnetic field.

In this case, the eddy currents create a braking force, because the induced currents prevent the flow from changing. Such forces are proportional to the speed of movement of the conducting surface and the strength of the magnetic field, which leads to a decrease in the rotational speed of the wind rotor. If the electromagnet has not reached saturation, and the speed continues to increase, then the controller gives a command to connect the next winding of the electromagnet. This happens until all the windings (9) of the electromagnet are involved, the number of which is one less than the number of phases of the generator (1), therefore, even with maximum braking, the generation of electricity continues to be supplied to the load.

Claims (9)

1. The system of adaptive stabilization of the wind rotor speed, which contains: - non-magnetic rotating conductive disc connected to the wind rotor, - electromagnetic unit, - controller with a given reference frequency value or with a given threshold voltage value, - a comparator connected to the phases of the wind rotor generator and to the controller and configured to analyze the frequency or voltage value of the signal input from the wind rotor generator, - in this case, the controller is configured to switch the voltage to the electromagnetic unit by means of commutating switches when the input voltage exceeds the threshold voltage or deviates from the reference frequency. 2. The system according to claim 1, characterized in that the electromagnetic unit is made in the form of a multi-winding electromagnetic unit located immovably relative to the wind rotor, and its pole piece is located with a gap <1 mm to the plane of a rotating non-magnetic conductive disk connected to the wind rotor. 3. The system according to claim 1, characterized in that the multi-winding electromagnetic unit is wound on a soft magnetic core with a high saturation induction. 4. The system according to claim 1, characterized in that the electromagnetic unit is made in the form of separate electromagnets, evenly distributed around the circumference of the non-magnetic conductive disk, and the number of electromagnets is less by one than the number of phases of the generator, and are made in such a way that each subsequent electromagnet is connected when saturation of the previous electromagnet and further increase in the rotational speed of the wind rotor.

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