KR20140084410A - Synchronous generator system haing dual rotor - Google Patents

Abstract

The present invention relates to a synchronous generator system. Specifically, provided is the generator system which can solve a problem of decrease in quick-response of constant voltage control generated by high inductance and non-resistance characteristics of the generator using superconducting field winding by using a normal conductive field coil to the generator which uses a superconducting field coil as the winding of the generator and adding a configuration controlling output voltage constantly according to fluctuating load.

Description

[0001] SYNCHRONOUS GENERATOR SYSTEM HAING DUAL ROTOR [0002]

The present invention relates to a synchronous power generation system, and more particularly, to a synchronous generator system having a dual rotor by combining a superconducting rotor having a superconducting account coil and a superconducting rotor having a superconducting field coil.

Generally, a synchronous generator is an alternator that converts mechanical power into electrical output. The relative speed of the rotor and the stator is rotated in synchronism with the rotating magnetic field.

Such a synchronous generator can be classified into a normal-phase generator and a superconducting generator according to the electromagnetism principle based on the field coil of the rotor.

The superconducting generator uses a superconducting field coil using copper as a rotor, and a superconducting generator uses a superconducting field coil as a rotor where superconducting phenomenon occurs at a relatively higher temperature than the phase conductor. The superconducting generator is a generator that uses superconductivity phenomenon in which electric resistance disappears at an absolute temperature of 0 K, that is, at -273 degrees Celsius. When a superconducting field coil is formed by a rotor, a high field magnetic field system can be produced without loss due to electrical resistance. For this reason, superconducting generators have the advantage of being more efficient, smaller in size, and smaller in weight compared to conventional superconducting generators.

1 is a block diagram of a normal-phase generator system.

The normal phase generator system includes an exciter 1 for generating a power source to be supplied to the DC field winding (rotor) of the main generator 3, a rectifier 1 for converting an AC power output from the exciter to a direct current (DC) 2, a main generator 3, a voltage sensor 4, and an automatic voltage regulator (AVR) 6, which are driven by a magnetic field between a stator and a rotor rotating with a DC power source do.

Since the time constant of the field winding is significantly lower than that of the superconducting generator system, the phase voltage generator system uses the automatic voltage regulator (6) to constantly control the output voltage that varies according to the load condition of the generator. The output voltage means a voltage that is output from the main generator 3 and applied to the system unit 5 and can be measured through the voltage sensor 4. [

2 is a block diagram of a superconducting generator system.

As shown in FIG. 2, the superconducting generator system includes an exciter 10, an AD-DC rectifier 20, a converter 30, a resistor 40, a superconducting generator 50, AVR: 60).

The superconducting generator system is characterized by applying a DC-DC converter (30) of several hundreds of kW class and a resistance for reducing the time constant to the field winding input, unlike the normal-conductor generator system.

The automatic voltage regulator 60 in the superconducting generator system measures the output voltage of the superconducting generator 50 in an externally fixed control system and wirelessly transmits a control signal to the converter 30 to generate a voltage necessary for the control .

However, the conventional superconducting generator system is structurally difficult to fix the DC-DC converter 30 and the resistor 40 to one rotation axis. In order to solve this problem, a separate mechanical device such as a brush is additionally constructed. However, this causes a loss as much as the capacity of the resistor, which causes a decrease in the efficiency of the system.

In addition, the superconducting field coil applied to the superconducting power generator 50 has a problem that the time constant of the field current control is remarkably lowered because the time constant is very large due to zero resistance and high inductance. That is, there is a problem that it is difficult to control in real time when the field current of the superconducting generator 50 is increased or decreased according to the load variation.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a superconducting generator in which the characteristics of a superconducting generator and the characteristics of an existing three- The present invention aims at providing a generator system capable of solving the problem of slowing down of the constant voltage control caused by high inductance and non-resistance characteristics of a generator using a superconducting field winding.

Another object of the present invention is to solve the structural difficulties of fixing a complicated control system of a generator to one rotation axis by simplifying a configuration in which the capacity of a control system becomes very large due to a DC-DC converter and a resistor configuration in a conventional superconducting generator I have to.

To this end, the synchronous generator system according to the first aspect of the present invention comprises: a hybrid generator which is composed of a superconducting field coil and a double rotor and a stator using the superconducting field coil as a winding of a generator, An exciter for generating a power source necessary for the superconducting field coil and the phase conductor coil of the hybrid generator; And a control unit that detects an output voltage output to the load from the hybrid generator, compares the detected output voltage with a reference value, and feeds back a variation corresponding to the deviation to the normal field coil so that the output voltage follows the reference value, And an automatic voltage regulator (AVR) for adjusting the current of the coil.

The synchronous generator system of the present invention further includes first and second rectifiers for converting an AC power generated by the exciter to a DC power required for the superconducting field coil and the phase field coil of the hybrid generator; Further comprising first and second converters for converting each of the DC power converted through the first and second rectifiers into a magnitude of a DC voltage required to control the superconducting field coil and the phase field coil of the hybrid generator .

Further, in the synchronous generator system of the present invention, the second converter regulates the current of the normal-phase field coil by receiving a variation amount corresponding to the deviation between the output voltage and the reference value from the automatic voltage regulating device.

Further, in the synchronous generator system of the present invention, the hybrid generator outputs a no-load voltage by a rotor constituted by the superconducting field coil and outputs a voltage according to a load variation by a rotor constituted by the normal field coil .

Further, in the synchronous generator system of the present invention, the hybrid generator includes: a first rotor that induces a magnetic flux for generating a no-load voltage using the superconducting field coil as a winding of a generator; A second rotor that rotates about the center and uses the normal field coil as a winding of the generator to induce a magnetic flux for generating a voltage in accordance with a load variation; and a second rotor for rotating the superconducting coil of the first rotor and the second rotor A rotor core for fixing the normal-conducting coil and for focusing the magnetic flux, and an air core for fixing the windings of the stator.

Further, in the synchronous generator system of the present invention, the exciter further includes a first armature winding for supplying power to the superconducting field coil, a second armature winding for supplying power to the normal field coil, A rotor core for fixing the first armature winding and the second armature winding and for focusing the magnetic flux, and a stator core for fixing the exciter (stator).

According to the present invention, by generating a no-load voltage by a rotor using a superconducting field coil and generating a voltage in accordance with a variable load by using a rotor using a superconducting field coil, The output voltage of the generator can be constantly controlled even if it has a high time constant. Thereby, there is an effect that the voltage applied to the system section connected to the rear end of the generator system can be stably supplied.

In addition, the structure of the DC-DC converter and the resistor configured for the constant voltage control in the conventional superconducting generator is simplified, thereby eliminating the structural difficulties in fixing the control system to one rotary shaft.

1 is a block diagram of a normal-phase generator system.
2 is a block diagram of a superconducting generator system.
3 is a configuration diagram of a synchronous generator system having a dual rotor according to an embodiment of the present invention.
4 is a block diagram of an exciter for implementing a synchronous generator system according to an embodiment of the present invention.
5 is a diagram illustrating a configuration of a hybrid type synchronous generator in a synchronous generator system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The configuration of the present invention and the operation and effect thereof will be clearly understood through the following detailed description. Before describing the present invention in detail, the same components are denoted by the same reference symbols as possible even if they are displayed on different drawings. In the case where it is judged that the gist of the present invention may be blurred to a known configuration, do.

3 is a configuration diagram of a synchronous generator system having a dual rotor according to an embodiment of the present invention.

3, a synchronous generator system (hereinafter referred to as a synchronous generator system) 100 having a dual rotor according to an embodiment of the present invention includes an exciter 110, first and second rectifiers 120 and 130, First and second converters 140 and 150, a hybrid generator 160 and an automatic voltage regulator (AVR) 170.

Here, the first rectifier 120 and the first converter 140 are configured to control the driving of the first rotor (or the superconducting rotor) 164 for inducing the magnetic flux to generate the no-load voltage, The rectifier 130 and the second converter 150 are configured to control the driving of the second rotor (or the normal-phase rotor) 166 for inducing a magnetic flux for generating a voltage in accordance with the variable load.

Therefore, in the synchronous generator system 100 according to the embodiment of the present invention, the first rotor 164 using the superconducting field coil and the second rotor 166 using the normal-field coil are arranged in a single generator in a hybrid form So as to provide an optimal configuration for the adaptive control.

The exciter 110 generates power necessary for the power generation of the hybrid generator 160. At this time, the power source generated through the exciter 110 is an AC power source and is applied to the first rectifier 120 and the second rectifier 130, respectively.

Particularly, although the exciter 110 can apply the same AC power to the first rectifier 120 and the second rectifier 130, due to the redundant structure of the hybrid generator 160, the first rectifier 120 and the second rectifier 130, The AC power to be applied to the rectifier 130 may be generated differently. In the latter case, one exciter 110 generates two levels of alternating current power and supplies them to the first rectifier 120 and the second rectifier 130 separately. The configuration of the exciter 110 for implementing this will be described in detail with reference to FIG.

The first and second rectifiers 120 and 130 receive the alternating current (AC) power outputted from the exciter 110 and convert them into a direct current (DC) power.

In particular, the first rectifier 120 converts the AC power generated by the exciter 110 into a DC power required for the superconducting field coil of the first rotor 164 of the hybrid generator 160.

The second rectifier 130 converts AC power generated by the exciter 110 into direct current power required for the field coil of the second rotor 166 of the hybrid generator 160.

The first converter 140 converts the DC power converted through the first rectifier 120 into a DC voltage magnitude required for controlling the superconducting field coil in the hybrid generator 160.

The second converter 150 converts the DC power converted through the second rectifier 130 into a DC voltage magnitude required for controlling the three-phase field coil in the hybrid generator 160.

The hybrid generator 160 mainly includes a stator 162 and a rotor 164 so that the rotor 164 rotates around a central axis of rotation and generates a magnetic field generated between the stator 162 and the rotor 164 .

Particularly, in the embodiment of the present invention, the rotor 164 is provided double, that is, two rotors, and is formed into a radial magnetic flux rotating magnetic field type.

The first rotor 164-1 uses a superconducting field coil as a winding of a generator to induce a magnetic flux for generating a no-load voltage at all times irrespective of load variations.

The second rotor 164-2 uses a normal field coil as a winding of a generator to induce a magnetic flux for generating a voltage in accordance with a load variation.

At this time, the first rotor 164-1 is rotated by the DC voltage converted through the first converter 140, and the second rotor 164-2 is rotated by the DC voltage converted through the second converter 150 It is rotated by voltage.

Also, the first and second rotors 164-1 and 164-2 are made of a non-magnetic material structure for winding the superconducting field coil or the superconducting field coil.

When the rotary shaft (not shown) of the generator is rotated at a predetermined speed, for example, 720 RPM, the hybrid generator 160 having the above-described configuration is operated so that the first rotor 164-1 of the hybrid generator 160 and the second rotor 164- 2) generate the magnetic field while rotating at the same speed, and develop according to the capacity of the generator. If the facility capacity of the generator is 2MW, the output voltage by the first rotor 164-1 constantly outputs the voltage of the generator facility capacity, that is, 6600V regardless of the variation of the load, and the second rotor 164-2 ) Adjusts the voltage according to the load variation within 1 to 2 seconds through the automatic voltage regulator 170 and outputs the adjusted output voltage.

The automatic voltage regulator 170 is a device that adjusts the output voltage output from the hybrid generator 160 to the system unit to maintain the rated voltage.

To this end, the automatic voltage regulator 170 detects an output voltage supplied to the system unit (load) and compares the detected output voltage with a reference value. Then, the control unit 150 controls the current of the second rotor 164-2 to be adjusted by feeding back the variation corresponding to the deviation to the second converter 150 so that the detected output voltage follows the reference value. The reference value means the rated voltage to be supplied to the system section.

Therefore, a synchronous generator system 100 having a dual rotor according to an embodiment of the present invention includes a first rotor 164-1 composed of a superconducting field coil and a second rotor 164-2 composed of a phase conductor coil ) Can be double-developed around one rotation axis to increase the power generation capacity, and real-time adaptive control can be performed according to the load variation, thereby solving the problem of using only the superconducting power generator.

4 is a configuration diagram showing an exciter of a synchronous generator system according to an embodiment of the present invention.

The exciter 110 according to the embodiment of the present invention is composed of an exciter (stator) and an exciter (rotor) 112 similar to the generator, and the exciter is a permanent magnet, an exciter 112 have a dual structure for supplying power to the dual rotors of the hybrid generator.

In particular, the exciter 112 has a first armature winding 112a for supplying power to the superconducting field coil of the first rotor, a second armature winding 112b for supplying power to the normal field coil of the second rotor The second electricity for supplying the second electronic power supply for supplying the electric power includes the winding 112b. The first armature winding 112a is electrically connected to the first rectifier (120 in Fig. 1) corresponding to the superconducting field coil, and the second armature winding 112b is electrically connected to the second rectifier 130 of the substrate 110).

The exciter further includes a rotor core made of a silicon steel sheet for fixing the stator core of the silicon steel sheet for fixation and magnetic flux focusing of the exciter (stator), fixing the exciter (rotor), and focusing the magnetic flux .

5 is a diagram illustrating a configuration of a hybrid type synchronous generator in a synchronous generator system according to an embodiment of the present invention.

The hybrid generator 160 according to the embodiment of the present invention includes dual rotors 164-1 and 164-2 using a superconducting field coil and a phase-change field coil as windings of a generator around a central shaft 166, And a stator 162 having a gap in the direction of the rotation axis 166 of the two rotors 164-1 and 164-2 and disposed opposite to the dual rotors 164-1 and 164-2.

The first rotor 164-1 of the dual rotors 164-1 and 164-2 includes a rotor core 164a-1 of non-magnetic material for winding the superconducting field coil 164c-1, And a bobbin 164b-1 for fixing the coil 164c-1.

The second rotor 164-2 includes a rotor core 164a-2 made of a silicon steel sheet for winding the normal-phase field coil 164b-2 and focusing the magnetic flux.

And may include an air core 162b made of glass fiber reinforced plastic (GFRP) for fixing the stator winding 162a.

Further, it may include a three-phase stator armature winding 162a made of copper that supplies power to the load and a mechanical shield 162c made of a cylindrical silicon steel sheet for shielding magnetic field leakage to the outside.

With this configuration, the hybrid generator 160 is configured such that the first rotor 164-1 using the superconducting field coil 164c-1 as a winding and the second rotor 164-1 using the superconducting field coil 164b- The first rotor 164-1 induces a magnetic flux for generating a no-load voltage while the former 164-2 rotates about the same rotational axis, and the second rotor 164-2 generates a voltage In order to generate the magnetic flux for generating the magnetic field. Therefore, even if the superconducting field coil has a high time constant due to the non-resistance and high inductance characteristics, the output voltage of the generator can be constantly controlled.

The foregoing description is merely illustrative of the present invention, and various modifications may be made by those skilled in the art without departing from the spirit of the present invention. Accordingly, the embodiments disclosed in the specification of the present invention are not intended to limit the present invention. The scope of the present invention should be construed according to the following claims, and all the techniques within the scope of equivalents should be construed as being included in the scope of the present invention.

100: Synchronous generator system 110: Exciter system
120, 130: first and second rectifiers 140, 150: first and second converters
160: Hybrid generator 170: Automatic voltage regulator

Claims (6)

A hybrid generator that is composed of a superconducting field coil and a double rotor and a stator using the field coil as a winding of the generator, and outputs a constant voltage even when the load fluctuates;
An exciter for generating a power source necessary for the superconducting field coil and the phase conductor coil of the hybrid generator; And
And a control unit that detects an output voltage output from the hybrid generator to the load, compares the detected output voltage with a reference value, feeds back a variation corresponding to the deviation to the normal field coil so that the output voltage follows the reference value, (AVR) that adjusts the current of the battery
Wherein the synchronous generator system has a dual rotor. The method according to claim 1,
First and second rectifiers for converting an AC power generated by the exciter to a DC power required for the superconducting field coil and the phase field coil of the hybrid generator;
The first and second converters converting the DC power supplied from the first and second rectifiers into a magnitude of a DC voltage required to control the superconducting field coil and the phase field coil of the hybrid generator,
Further comprising a dual rotor. 3. The method of claim 2,
Wherein the second converter receives the variation amount corresponding to the deviation between the output voltage and the reference value from the automatic voltage adjusting device and adjusts the current of the normal phase field coil. The method according to claim 1,
The hybrid generator
And a voltage generator for generating a voltage corresponding to a load variation by a rotor constituted by the superconducting field coil and outputting a no-load voltage by a rotor constituted by the superconducting field coil. The method according to claim 1 or 4,
The hybrid generator includes:
A first rotor for inducing a magnetic flux for generating a no-load voltage using the superconducting field coil as a winding of a generator,
A second rotor that rotates about the same rotational axis as the first rotor and uses the normal field coil as a winding of the generator to induce a magnetic flux for generating a voltage in accordance with a load variation;
A rotor core for fixing the superconducting coil of the first rotor and the superconducting coil of the second rotor and for focusing the magnetic flux,
An annular core for fixing the windings of the stator
Wherein the synchronous generator system has a dual rotor. The method according to claim 1,
In the exciter,
A first armature winding for supplying power to the superconducting field coil,
A second armature winding for supplying power to the normal field coil;
A rotor core for holding said first armature winding and said second armature winding and for focusing magnetic fluxes,
Stator core for fixing the exciter (stator)
Wherein the synchronous generator system has a dual rotor.

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