JP4804211B2 - DC output circuit of power generator for distributed power supply - Google Patents

Description

  The present invention relates to a main circuit of a power generator for a distributed power source that extracts an approximate maximum output obtained from wind or water from a permanent magnet generator driven by a wind turbine or water turbine, regardless of wind speed or flow velocity. The present invention relates to a DC output circuit of a power generator for a distributed power source that performs constant voltage charging without using a PWM converter from a magnet generator.

  In order to obtain an approximate maximum output from a permanent magnet generator connected to a windmill or a water turbine without using a PWM converter, the present applicant firstly uses a different permanent magnet generator. Proposing a distributed power generator that connects rectifiers in series via each reactor to the AC output terminals of multiple windings that generate induced voltage, and outputs the rectifier's DC output in parallel. (For example, refer to Patent Document 1).

The prior application technique will be described in detail with reference to a main circuit connection diagram showing a power generator for a distributed power source connected to the wind turbine of FIG.
In FIG. 13, 1 is a windmill, 2 is a power generator for distributed power supply of the prior application, 3 is a permanent magnet generator, 4 and 6 are first and second reactors, and 8 and 10 are first and second reactors. A rectifier, 12 is a positive output terminal, 13 is a negative output terminal, and 14 is a battery.
FIG. 13 shows a case where the permanent magnet generator 3 has two types of windings and each winding has three phases.

In FIG. 13, since the number of turns of the permanent magnet generator 3 is small, the AC output terminal W1 of the first winding having a low induced voltage effective value is connected to the first reactor 4, and further to the first rectifier 8. Connected.
The AC output terminal W2 of the second winding having a large number of turns is connected to the second reactor 6 and further connected to the second rectifier 10.
The direct current sides of the first and second rectifiers 8 and 10 are connected in parallel to the positive output terminal 12 and the negative output terminal 13, and the total output of each winding is charged in the battery 14.

A method of obtaining a rough maximum wind turbine output from the power generator 2 for a distributed power source configured as described above will be described below.
FIG. 10 is a diagram for explaining the outline of the wind turbine rotation speed versus the wind turbine output characteristic when the wind speed is used as a parameter.
When the shape of the windmill and the wind speed U are determined, the windmill output P with respect to the windmill rotation speed N is uniquely determined. For example, the windmill output P with respect to the wind speeds Ux and Uy is shown as in FIG. And the peak of the windmill output P with respect to various wind speeds becomes like the maximum output curve Pt shown in FIG.
That is, when the wind speed is Ux in the wind turbine rotational speed vs. wind turbine output characteristic of FIG. 10, the wind turbine maximum output Px at the wind turbine rotational speed Nx as indicated by the intersection Sx of the wind turbine output curve of the wind speed Ux and the maximum output curve. It becomes.
When the wind speed is Uy, the windmill maximum output Py at the wind speed Uy is obtained at the windmill rotational speed Ny.

  That is, when the way of viewing the maximum output curve in FIG. 10 is changed, in order to obtain the maximum output from the wind, when the wind turbine rotation speed N is determined, the output P of the permanent magnet generator 3 at that time is uniquely determined as the maximum output. This indicates that the value may be determined on the curve Pt.

  FIG. 11 is an explanatory diagram in the case where the DC output of the distributed power generator 2 targeted by the prior application technology is connected to a constant voltage source such as a battery, and the permanent magnet generator 3 of the distributed power generator 2. Each output of the first and second windings of FIG. 11 is caused by the difference in effective value of the induced voltage of each winding, and the voltage drop due to the internal inductance of each winding and the reactor connected to each output terminal. P1 and P2 shown in the number vs. output characteristics are obtained.

That is, when the wind turbine rotation speed N is low, the voltage generated in the first and second windings in the permanent magnet generator 3 is lower than the battery voltage Vb, so the battery 14 is not charged.
However, when the wind turbine rotational speed N rises and becomes near N2, the current starts to flow through the second winding, and the current increases as the wind turbine rotational speed N increases, and the output from the second winding is P2. become.
At this time, even if the wind turbine rotation speed N increases and the induced voltage increases, the battery voltage is almost constant, but the inductance of the second winding and the impedance of the second reactor 6 are proportional to the frequency. At the same time, the output P2 only increases gradually.
With respect to the first winding, output begins to be obtained as the rotational speed N further increases, and a large output can be obtained because the internal inductance of the first winding and the first reactor 4 are small.

FIG. 12 is a diagram illustrating an output to a constant voltage source such as a battery of the distributed power generation device targeted by the prior application.
The total output obtained by adding the outputs P1 and P2 of the first and second windings in the permanent magnet generator 3 is an approximate output curve Ps.
JP 2004-64928 (FIG. 1)

However, when the electric power is obtained from the main circuit of the distributed power generator 2 as described above, the AC output by the winding of the permanent magnet generator 3 is a delayed current, so that the gap magnetic flux of the permanent magnet generator 3 is This is a direction in which the internal induced voltage decreases and the output of the power generator 2 for the distributed power source decreases.
In particular, the second winding with a large number of turns has a small amount of current flowing. However, since the number of turns is large, the influence of the demagnetization action proportional to the product of the lag current and the number of turns becomes large, and the first winding with a small number of turns. Can not produce a large AC output.

When the influence of this demagnetizing action is seen in the output to a constant voltage source such as a battery of the conventional distributed power generator 2 in FIG. 12, when the wind turbine rotational speed N is large, the maximum output curve Pt and the approximate output curve Ps The output difference Pz that is the difference between the two becomes large.
In order to reduce this demagnetizing action, for example, the thickness of the permanent magnet in the permanent magnet generator 3 in the magnetic flux direction must be increased.

  The present invention has been made in view of the above circumstances. The main purpose of the present invention is to reduce the amount of expensive permanent magnets in the permanent magnet generator 3 and reduce the price of the permanent magnet generator 3. Another object of the present invention is to provide a DC output circuit of a power generator for a distributed power source that can reduce and substantially match the maximum output curve Pt and the approximate output curve Ps even when the wind turbine rotational speed N is large.

The invention according to claim 1
The AC output of the permanent magnet generator winding composed of a plurality of windings driven by a windmill or water turbine to generate different induced voltage effective values is rectified by an individual rectifier, and the direct current of the individual rectifier In a DC output circuit of a power generator for a distributed power source that adds outputs in parallel and outputs them to the outside, the individual AC output terminals of the windings that generate a low induced voltage effective value among the plurality of windings via a reactor And connecting the individual rectifier via a reactor to an AC output terminal of a winding that generates a high induced voltage effective value among the plurality of windings and the individual rectifier via a capacitor. Capacitor series rectifier circuit for connecting a rectifier is connected in parallel, the inductive impedance due to the internal inductance of the winding generating the high induced voltage effective value and the capacitor Series combined impedance of the capacitive impedance due is a direct current output circuit features and to have distributed power electric generation system that such a capacitive impedance in the rated rotational speed range of the permanent magnet generator.

The invention according to claim 2
In the invention according to claim 1, there is provided a DC output circuit of a power generator for a distributed power source, wherein the plurality of windings are of two types.

The invention according to claim 3
In the DC output circuit of the power generator for a distributed power source according to the first aspect of the present invention, there are three types of the plurality of windings, and the winding that generates the lowest induced voltage effective value among the three types of windings. A reactor is connected in series between the AC output terminal of the wire and the individual rectifier, and the reactor is connected to the AC output terminal of the winding that generates the second highest induced voltage effective value among the three types of windings. A reactor series rectifier circuit that connects the individual rectifiers and a capacitor series rectifier circuit that connects the individual rectifiers via a capacitor are connected in parallel, and the highest induced voltage effective value among the three types of windings is obtained. A reactor is connected in series between the AC output terminal of the generated winding and the individual rectifier, and the internal inductance of the winding generating the second highest induced voltage effective value among the three types of windings. Inductive in A DC output circuit for a power generator for a distributed power source, characterized in that a series combined impedance of an impedance and a capacitive impedance by the capacitor is a capacitive impedance within a rated rotational speed range of the permanent magnet generator It is.

The invention according to claim 4
In a DC output circuit of a distributed power generator that rectifies an AC output of a permanent magnet generator driven by a windmill or a water turbine by an individual rectifier and outputs it to the outside, a reactor is connected to an AC output terminal of the permanent magnet generator A reactor series rectifier circuit that connects the individual rectifiers via a capacitor and a capacitor series rectifier circuit that connects the individual rectifiers via a capacitor are connected in parallel to form a series combination of the internal inductance of the permanent magnet generator and the capacitor. The DC output circuit of the power generator for a distributed power source is characterized in that the impedance is a capacitive impedance within a rated rotational speed range of the permanent magnet generator.

  The amount of expensive permanent magnets in the permanent magnet generator 3 is reduced to reduce the price of the permanent magnet generator 3, and the maximum output curve Pt and the approximate output curve Ps are almost equal even when the wind turbine rotational speed N is large. It is possible to provide a DC output circuit of a power generator for a distributed power source that can be matched. Further, even when the wind turbine rotational speed N is small, power can be generated by the reactor series rectifier circuit, and when the wind turbine rotational speed N increases, a plurality of windings in the permanent magnet generator 3 are generated by a magnetizing action by a capacitor. The number of turns of the wire can be reduced, and the generator can be downsized.

  A plurality of AC outputs of a permanent magnet generator composed of a plurality of windings that generate different induced voltage effective values are rectified by individual rectifiers, and the DC outputs of the individual rectifiers are added and output to the outside. In a DC output circuit of a power generator for a distributed power supply, a reactor series rectifier circuit that connects the individual rectifier via a reactor is connected to an AC output terminal of a winding that generates a high induced voltage effective value among the plurality of windings. And a capacitor series rectifier circuit that connects the individual rectifier via a capacitor to an AC output terminal of a winding that generates a high effective value of the induced voltage of the winding, and a high induced voltage of the permanent magnet generator The combined impedance of the capacitor connected in series with the internal inductance of the winding generating the effective value is within the rated rotational speed range of the permanent magnet generator. It is intended to be a sex impedance.

FIG. 1 is a diagram for explaining a DC output circuit of a power generator for a distributed power source that obtains a DC output from a wind turbine or a water turbine according to the present invention.
In the figure, 7 is a capacitor, 11 is a rectifier connected to the capacitor, and the same numbers as those in FIG. 13 represent the same components.
Hereinafter, FIG. 1 will be described with reference to FIGS. 5 and 6 illustrating the principle of the present invention.

The reactor 6 and the second rectifier 10 are connected in series to the AC output terminal W2 of the second winding having a large number of turns. Furthermore, the capacitor 7 and the third rectifier 11 are connected in series to the AC output terminal W2 of the second winding. The first reactor 4 is connected to the AC output terminal W1 of the first winding having a small number of turns, and the first rectifier 8 is further connected in series.
The outputs of the first rectifier 8, the second rectifier 10 and the third rectifier 11 are connected in parallel, and the total DC output thereof is charged in the battery 14.

Here, the reactor 6 connected to the second winding is designed so that an output can be obtained even when the wind turbine rotational speed N is small. Furthermore, the combined impedance of the inductive impedance due to the internal inductance of the second winding and the capacitive impedance due to the capacitor 7 connected in series is the capacitive impedance within the rated rotational speed range of the permanent magnet generator 3. Thus, the capacitor 7 is designed based on the internal inductance of the second winding in the permanent magnet generator 3.
By designing in this way, when the rotational speed of the wind turbine exceeds a certain value, an AC current in which the effective current to the battery 14 and the phase-advanced current due to the capacitive impedance are added in vector flows through the second winding. .

The output of each winding to the constant pressure power source of the distributed power generator 2 targeted by the present application will be described with reference to FIG.
When the wind turbine rotation speed N is low, the voltage generated in the second winding is lower than the battery voltage Vb, so the battery 14 is not charged. However, increased wind turbine's rotational speed N is equal to or near the N2, a current begins to flow through the reactor 6 and a rectifier 10, a DC output which flows through the reactor 6 becomes P _L. At this time, since the impedance of the capacitor 7 large, the DC output P _C flowing through the capacitor 7 is small. Therefore, until the wind turbine rotation speed N2 'vicinity, the DC output P _L that flows through the total output P2 and the reactor 6 of the second winding which flows through the capacitor 7 and the reactor 6 is approximately equal.

The increase of the wind turbine rotational speed N, the frequency and the induced voltage of the permanent magnet generator 3 is increased, the internal inductance and the reactor 6 of the second winding, the output P _L in the impedance is proportional to the frequency increasing Stay on. However, the capacitor 7 increases together output P _C increased by the induced voltage in order to reduce the impedance in proportion to the frequency is proportional to the square of the rotational speed. That is, the current flowing through the capacitor 7 and the rectifier 11 becomes larger than the current flowing through the reactor 6 near the wind turbine speed N2 ′. Then, the AC output current from the second winding increases in proportion to the square of the frequency in combination with the increase of the induced voltage.

  Further, when the rotational speed of the wind turbine is N2 ′ or higher, the current corresponding to the phase advance is caused to flow by the capacitor 7 of the second winding, so that the gap magnetic flux of the permanent magnet generator 3 is increased. The internal induced voltage of the winding and the second winding increases.

As the wind turbine rotation speed N increases, the first winding having a small internal inductance or the like starts to obtain a large output.
Accordingly, the outputs of the first and second windings of the permanent magnet generator 3 of the power generator 2 for the distributed power source are connected to the difference in the effective value of the induced voltage of each winding, the internal inductance of each winding, and each output terminal. Due to the voltage drop caused by the reactor or the capacitor, P1 and P2 shown in the wind turbine rotation speed versus output characteristic of FIG. 5 are obtained.

FIG. 6 is a diagram illustrating the total output of each winding to a constant voltage source such as a battery of the power generator 2 for the distributed power source targeted by the present application.
Here, since the second winding passes a current corresponding to the phase advance, the internal induced voltage of the first winding increases. However, due to the demagnetizing action due to the slow phase current of the first winding itself, the magnetizing action due to the phase advance current of the second winding is suppressed as the first winding current increases.
However, as a whole, the total output obtained by adding the outputs P1 and P2 of the first and second windings by the magnetizing action by the phase advance current of the second winding is the conventional approximate output of FIG. The output becomes larger than the curve Ps, and an output like the approximate output curve Ps shown in FIG. 6 can be obtained, and an output similar to the maximum output curve Pt can be obtained.

FIG. 2 shows a second embodiment of the present invention.
FIG. 2 is a diagram showing a DC output circuit of a power generator for a distributed power source when the present invention is applied to a winding having three types of windings in the permanent magnet generator 3 and having the largest number of turns. is there.
In the same figure, 5 is a reactor, 9 is a rectifier, and the same number as FIG.1 and FIG.13 represents the same component.
Hereinafter, FIG. 2 will be described.

A third reactor 6 and a third rectifier 9 are connected in series to the AC output terminal W3 of the third winding having a large number of turns in the permanent magnet generator 3. Further, the capacitor 7 and the fourth rectifier 11 are connected. Are connected in series. Next, the second reactor 5 and the second rectifier 9 are connected in series to the AC output terminal W2 of the second winding having the largest number of turns. The first reactor 4 and the first rectifier 8 are connected in series to the AC output terminal W1 of the first winding with the smallest number of turns.
The outputs of the first to fourth rectifiers 8 to 11 are connected in parallel, and the total DC output is charged to the battery 14.

Here, the reactor 6 connected to the third winding is designed so that an output can be obtained even when the wind turbine rotational speed N is low. Furthermore, the combined impedance of the inductive impedance due to the internal inductance of the third winding and the capacitive impedance due to the capacitor 7 connected in series is the capacitive impedance within the rated rotational speed range of the permanent magnet generator 3. Thus, the capacitor 7 is designed based on the internal inductance of the third winding in the permanent magnet generator 3.
By designing in this way, when the rotational speed of the wind turbine exceeds a certain value, the third winding has an alternating current obtained by adding an effective current to the battery 14 and a phase-advanced current due to capacitive impedance in vector form. Flowing.

When the wind turbine speed N is low, the voltage generated by the third winding is lower than the battery voltage Vb, so the battery 14 is not charged. However, increased wind turbine's rotational speed N is equal to or near N3, current starts to flow through the reactor 6 and a rectifier 10, a DC output which flows through the reactor 6 becomes P _L. At this time, due to the large impedance of the capacitor 7, the DC output P _C flowing through the capacitor 7 is small. Therefore, until the wind turbine rotation speed N3 'vicinity, the DC output P _L that flows through the total output P3 and the reactor 6 of the third winding which flows through the capacitor 7 and the reactor 6 is approximately equal.

The increase of the wind turbine rotational speed N, the frequency and the induced voltage of the permanent magnet generator 3 is increased, the internal inductance and the reactor 6 of the third winding, the output P _L in the impedance is proportional to the frequency increasing Stay on. However, the capacitor 7 increases together output P _C increased by the induced voltage in order to reduce the impedance in proportion to the frequency is proportional to the square of the rotational speed. That is, the current flowing through the capacitor 7 and the rectifier 11 becomes larger than the current flowing through the reactor 6 near the wind turbine speed N3 ′. Then, the AC output current from the third winding increases in proportion to the square of the frequency in combination with the increase of the induced voltage.

In addition, since the third winding includes a current corresponding to the phase advance, it is a direction to increase the gap magnetic flux of the permanent magnet generator 3, and when a current flows through the third winding, The internal induced voltage of the third winding increases.
However, due to the demagnetizing action of the first and second windings due to the slow-phase current, the magnetizing action due to the phase-advancing current of the third winding is suppressed as the first and second winding currents increase. The

FIG. 7 shows the output of each winding in the second embodiment of the present invention. The output of each winding increases as the wind turbine rotational speed N increases. In particular, the output of the third winding The rotation speed N increases in proportion to the square of the frequency.
The total output obtained by adding the outputs P1 to P3 of the first to third windings is the case of two windings shown in FIG. 6 because the permanent magnet generator 3 has three types of windings. The output approximated to the maximum output curve Pt can be obtained more than the approximate output curve Ps.

FIG. 3 shows a third embodiment of the present invention.
FIG. 3 shows a case in which there are three types of windings in the permanent magnet generator 3, and a generator for a distributed power source when the present invention is applied to an AC output terminal of a winding having the second largest number of turns. It is a figure which shows the direct current | flow output circuit.
In the figure, 7 is a capacitor and 11 is a rectifier. 2 and 13 denote the same components.
Hereinafter, FIG. 3 will be described with reference to FIG.

A third reactor 6 is connected to the AC output terminal W3 of the third winding having the largest number of turns, and a fourth rectifier 10 is further connected in series.
Next, the second reactor 5 and the second rectifier 9 are connected in series to the AC output terminal W2 of the second winding having the next largest number of turns, and further the capacitor 7 and the third rectifier 11 are connected in series. .
The first reactor 4 is connected to the AC output terminal W1 of the first winding with the smallest number of turns, and the first rectifier 8 is further connected in series.
The outputs of the first to fourth rectifiers 8 to 11 are connected in parallel, and the total DC output is charged to the battery 14.

Here, the reactor 5 connected to the second winding is designed so that an output can be obtained even when the wind turbine rotational speed N is small. Furthermore, the combined impedance of the inductive impedance due to the internal inductance of the second winding and the capacitive impedance due to the capacitor 7 connected in series is a capacitive impedance within the rated rotational speed range of the permanent magnet generator 3. The capacitor 7 is designed based on the internal inductance of the winding in the permanent magnet generator 3 so that
By designing in this way, when the rotational speed of the wind turbine is exceeded, a current corresponding to the leading phase flows through the second winding.

  When the wind turbine speed N is low, the voltage generated in each winding is lower than the battery voltage Vb, so the battery 14 is not charged. However, when the wind turbine rotation speed N increases and becomes near N3, current begins to flow through the reactor 6 and the rectifier 10 connected to the third winding, and the DC output flowing through the reactor 6 becomes P3. This DC output P3 increases as the wind turbine speed increases, but the output P3 only increases gradually because the impedance is proportional to the frequency due to the internal inductance of the third winding and the reactor 6.

Further wind turbine's rotational speed increases and becomes near the windmill rotation speed N2, current starts to flow through the reactor 5 and a rectifier 9, the DC output which flows through the reactor 5 becomes P _L. At this time, due to the large impedance of the capacitor 7, the DC output P _C flowing through the capacitor 7 is small. Therefore, until the wind turbine rotation speed N2 'vicinity, the DC output P _L that flows through the total output P2 and the reactor 5 of the second winding which flows through the capacitor 7 and the reactor 5, is approximately equal.

The increase of the wind turbine rotational speed N, the frequency and the induced voltage of the permanent magnet generator 3 is increased, the internal inductance and the reactor 5 of the second winding, the output P _L the impedance is proportional to the frequency gradually increases . However, the capacitor 7 is output P _C with increasing the induced voltage in order to reduce the impedance in proportion to the frequency increases in proportion to the square of the rotational speed. Therefore, the current flowing through the capacitor 7 and the rectifier 11 becomes larger than the current flowing through the reactor 5 near the wind turbine speed N2 ′. Then, coupled with the increase of the induced voltage, the output of the second winding increases in proportion to the wind turbine speed N, that is, the square of the frequency.
In addition, since the second winding is carrying a current corresponding to the phase advance, it is a direction to increase the gap magnetic flux of the permanent magnet generator 3, and the wind turbine rotation speed increases, When current starts to flow, the internal induced voltage of the first to third windings increases.
Further, as the wind turbine rotation speed N increases, the first winding having a small internal inductance or the like starts to obtain a large output.

FIG. 8 shows the output of each winding in the third embodiment of the present invention. The output of each winding increases as the wind turbine rotational speed N increases. In particular, the output of the second winding The number of rotations N, that is, the frequency increases almost in proportion to the two items.
The total output obtained by adding the outputs P1 to P3 of these first to third windings is based on the approximate output curve Ps shown in FIG. 6 because the permanent magnet generator 3 has three types of windings. Also, an output that approximates the maximum output curve Pt can be obtained.
However, due to the demagnetizing action of the first and third windings due to the slow phase current, the magnetizing action due to the fast current of the second winding is suppressed as the first and third winding currents increase. The

  When the capacitor 7 is connected in series to the second winding having the second largest number of turns as described above, a large amount of current flows through the capacitor 7 and the internal impedance of the second winding is small. Although the capacity seems to increase, since the range of the windmill speed N through which the phase advance current flows is narrow, the capacity of the capacitor 7 for making the capacitive impedance within the rated speed range may be small. There are advantages.

FIG. 4 shows a fourth embodiment of the present invention.
FIG. 4 is a diagram showing a DC output circuit of a power generator for a distributed power source when the present invention is applied when the number of windings in the permanent magnet generator 3 is one.
In the figure, the same reference numerals as those in FIGS. 1 and 13 denote the same components.
Hereinafter, FIG. 4 will be described.

A reactor 4 and a first rectifier 8 are connected in series to the AC output terminal W1 of the first winding, and a capacitor 7 and a second rectifier 11 are connected in series to the AC output terminal W1 of the first winding. Connected to.
Here, the reactor 4 connected to the first winding is designed so that an output can be obtained even when the wind turbine rotational speed N is small. Furthermore, the series combined impedance of the inductive impedance due to the internal inductance of the first winding and the capacitive impedance due to the capacitor 7 connected in series is the capacitive impedance within the rated rotational speed range of the permanent magnet generator 3. Thus, the capacitor 7 is designed based on the internal inductance of the winding in the permanent magnet generator 3.

By designing in this way, when the wind turbine rotational speed N increases and the induced voltage of the first winding becomes larger than the battery voltage Vb, the first winding has a current to the phase advance and the battery voltage Vb. An effective current that is a charging current flows.
Therefore, when a current starts to flow through the first winding, the internal induced voltage of the first winding increases due to the phase advance current.

FIG. 9 shows the output of the first winding in the fourth embodiment of the present invention. When the wind turbine rotational speed N rises and the wind turbine rotational speed N becomes near N1, it passes through the reactor 4 and the rectifier 8. current starts to flow, a DC output which flows through the reactor 4 becomes P _L. At this time, due to the large impedance of the capacitor 7, the DC output P _C flowing through the capacitor 7 is small. Thus, wind turbine speed N to the vicinity of the N1 'includes a DC output P _L that flows through the total output P1 and the reactor 4 of the first winding is approximately equal.

The increase of the wind turbine rotational speed N, the frequency and the induced voltage of the permanent magnet generator 3 is increased, the internal inductance and the reactor 4 of the first winding, the impedance gradually increases output P _L proportional to the frequency . However, the capacitor 7 is output P _C with increasing the induced voltage in order to reduce the impedance in proportion to the frequency increases in proportion to the square of the rotational speed. That is, the current flowing through the capacitor 7 and the rectifier 11 becomes larger than the current flowing through the reactor 4 near the windmill speed N1 ′. Then, coupled with the increase of the induced voltage, the output of the first winding increases in proportion to the wind turbine speed N, that is, the square of the frequency.
The DC output P1 of the first winding is not approximated to the maximum output curve Pt than the approximate output curve Ps of FIG. 5, but since the gap magnetic flux of the permanent magnet generator 3 is increased, An output approximate to the maximum output curve Pt can be obtained by a simpler method than the main circuit of the distributed power generation apparatus to which only the rectifier is connected.

  According to the DC output circuit of the distributed power generator of the present invention, the maximum output curve Pt and the approximate output curve Ps can be substantially matched even when the wind turbine rotational speed N is large, and the permanent magnet generator 3 It is possible to reduce the price of the permanent magnet generator 3 by reducing the amount of expensive permanent magnets.

  In addition, since there is a magnetizing action of the winding with a large number of turns due to the connection of the capacitor, the necessary induced voltage can be obtained even if the number of turns of the winding with a small number of turns is reduced. By reducing the winding space, the size and weight of the permanent magnet generator 3 can be reduced. Accordingly, the permanent magnet generator is lighter and the entire nacelle is lighter even when it is housed in the nacelle of the propeller type windmill, which is very useful in practice.

  The DC output circuit of the power generator for a distributed power source according to the present invention has a permanent magnet type so that the leading current or the lagging current of each winding is optimized at the rotation speed at which the efficiency of the permanent magnet generator is to be maximized. The total copper loss of the generator can be minimized.

  Further, when the internal inductance of the permanent magnet generator 3 and the capacitor 7 resonate, the impedance becomes only the resistance and a large current flows. Therefore, if the capacity of the capacitor 7 is determined so that the resonance state occurs above the rated rotational speed of the permanent magnet generator 3, it can be an electric brake for stopping the windmill that gradually operates as the rotational speed increases.

  The direct current output circuit of the power generator for a distributed power source according to the present invention does not require an anemometer or an expensive PWM converter, and further reduces the number of permanent magnets in the permanent magnet generator, so that it can be configured at low cost. The PWM converter eliminates the need for standby power, which can increase the amount of power generation throughout the year and is extremely useful in practice.

  In the above description of the second and third embodiments, it has been described that the capacitor 7 is connected to the winding having the largest number of turns or the second largest number of windings. The capacitor 7 may be connected to both windings.

The above has been described with reference to wind power. However, for example, if the shape of a water turbine is determined like hydraulic power, the present invention can also be applied to applications in which the rotational speed versus output characteristics when the maximum output is taken out are uniquely determined.
In the above description, the description has been made with three phases, but the present invention can also be applied to a single phase and other numbers of phases.
Furthermore, in the first to fourth embodiments, it has been described that the first reactor 4 is connected to the AC output terminal W1 of the first winding. However, the necessary inductance value of the first reactor 4 is reduced. It is possible to design the permanent magnet generator 3 and delete the first reactor.

It is a figure for demonstrating the direct current | flow output circuit of the generator device for distributed power supplies driven by a windmill of this invention. DC output circuit diagram of a distributed power generator for explaining a second embodiment when the present invention is applied to a winding having three types of windings in the permanent magnet generator and having the largest number of turns. Is DC output circuit of a power generator for a distributed power source for explaining a third embodiment in which the present invention is applied to a winding having three types of windings in the permanent magnet generator and the second largest number of windings FIG. FIG. 10 is a DC output circuit diagram of a distributed power generator for explaining a fourth embodiment of the present invention, which is applied when the number of windings in a permanent magnet generator is one; It is a figure for demonstrating the output of each coil | winding in the 1st Example of this invention. It is a figure for demonstrating the output to constant voltage sources, such as a battery, of the generator device for distributed power supplies which this application makes object. It is a figure for demonstrating the output of each coil | winding in the 2nd Example of this invention. It is a figure for demonstrating the output of each coil | winding in the 3rd Example of this invention. It is a figure for demonstrating the output of each coil | winding in the 4th Example of this invention. It is a figure explaining the outline | summary of a windmill rotation speed versus windmill output characteristic when a wind speed is made into a parameter. It is a figure for demonstrating the output of each coil | winding of the power generator for distributed power supplies which a prior application makes object. It is a figure for demonstrating the output to constant voltage sources, such as a battery, of the generator device for distributed power supplies which a prior application makes object. It is a main circuit diagram of the power generator for distributed power supplies of a prior application.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Windmill 2 Distributed power generator 3 Permanent magnet generator 4 1st reactor 5 2nd reactor 6 3rd reactor 7 Capacitor 8 1st rectifier 9 2nd rectifier 10 3rd rectifier 11 4th Rectifier 12 Positive output terminal 13 Negative output terminal 14 Battery

Claims (4)

The AC output of the permanent magnet generator winding composed of a plurality of windings driven by a windmill or water turbine to generate different induced voltage effective values is rectified by an individual rectifier, and the direct current of the individual rectifier In a DC output circuit of a power generator for a distributed power source that adds outputs in parallel and outputs them to the outside, the individual AC output terminals of the windings that generate a low induced voltage effective value among the plurality of windings via a reactor And connecting the individual rectifier via a reactor to an AC output terminal of a winding that generates a high induced voltage effective value among the plurality of windings and the individual rectifier via a capacitor. Capacitor series rectifier circuit for connecting a rectifier is connected in parallel, the inductive impedance due to the internal inductance of the winding generating the high induced voltage effective value and the capacitor Series combined impedance of the capacitive impedance by the said permanent magnet generator DC output circuit of distributed power for power generation apparatus, which comprises such a capacitive impedance in the engine speed range rating. 2. The DC output circuit for a distributed power generator according to claim 1, wherein the plurality of windings are of two types. 2. The DC output circuit of the power generator for a distributed power source according to claim 1, wherein the plurality of windings are of three types, and an AC of a winding that generates the lowest induced voltage effective value among the three types of windings. A reactor is connected in series between the output terminal and the individual rectifier, and the individual output through the reactor to the AC output terminal of the winding that generates the second highest induced voltage effective value among the three types of windings. A reactor series rectifier circuit that connects the rectifiers of this type and a capacitor series rectifier circuit that connects the individual rectifiers via a capacitor are connected in parallel, and the winding that generates the highest effective value of the induced voltage among the three types of windings. An inductive impedance of an internal inductance of a winding that connects a reactor in series between the AC output terminal of the wire and the individual rectifier and generates the second highest induced voltage effective value among the three types of windings When Serial series combined impedance of the capacitive impedance due to the capacitor, said permanent magnet generator DC output circuit of distributed power for power generation apparatus, which comprises such a capacitive impedance in the engine speed range rating. In a DC output circuit of a distributed power generator that rectifies an AC output of a permanent magnet generator driven by a windmill or a water turbine by an individual rectifier and outputs it to the outside, a reactor is connected to an AC output terminal of the permanent magnet generator A reactor series rectifier circuit that connects the individual rectifiers via a capacitor and a capacitor series rectifier circuit that connects the individual rectifiers via a capacitor are connected in parallel to form a series combination of the internal inductance of the permanent magnet generator and the capacitor. A DC output circuit of a power generator for a distributed power source, wherein the impedance is a capacitive impedance within a rated rotational speed range of the permanent magnet generator.

Images