JPH0880061A - Stationary variable-frequency and variable-voltage power supply - Google Patents

Abstract

PURPOSE: To provide a stationary variable-frequency and variable-voltage power supply device capable of increasing the rotational speed of a motor to a maximum rated rotational speed at the time of the single-body test of the motor by varying the main circuit constant of a current type inverter circuit. CONSTITUTION: In a stantionary variable-frequency and variable-voltage power supply device driving a motor, commutation capacitors 10a-10c mounted on a current type inverter circuit consist of a plurality of unit capacitors 10a1 -104 , 10b1 -104 , 10c1 -l0c4 , and the partial unit capacitors 10a1 , 10b1 , 10c1 are separated and connected in parallel through disconnectors 11a-11c.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a static variable frequency variable voltage power supply device using a current type inverter circuit, and more particularly to a static variable frequency variable voltage power supply capable of performing a unit test of a driving motor at a maximum rated rotation speed. Regarding the device.

[0002]

2. Description of the Related Art In a static type variable frequency variable voltage power supply device, there are a voltage type and a current type in its inverter circuit. The voltage type is suitable for a small capacity and the current type is suitable for a large capacity.
Therefore, for example, as a drive power source for a recirculation pump installed in a boiling water reactor, a static variable frequency variable voltage power supply device using a current source inverter is adopted because the drive motor of the recirculation pump has a large output. ing.

An outline of a conventional static variable frequency variable voltage power supply device for speed control of an electric motor will be described with reference to the circuit configuration diagram of FIG. The current source variable frequency variable voltage power supply device uses an AC power supply 1 with an input transformer 2 as a rectifier circuit constituent element 3a.
This rectifier circuit component 3 is converted into a voltage suitable for 3f.
AC power is rectified to DC power at a to 3f.

After the DC power is smoothed by the DC reactor 4, the DC power is converted into an AC of a predetermined frequency in an inverter circuit formed by thyristors 5a to 5f, commutation capacitors 6a to 6f and diodes 7a to 7f. It is configured such that it is converted back into electric power, and this AC power is further boosted to an appropriate voltage by the output transformer 8 and supplied to the electric motor 9.

Further, the configuration diagram of the main part of FIG. 6 shows the details of the + side of the inverter circuit, and all of the commutation capacitors 6a to 6c can easily obtain a desired electrostatic capacitance. For example, four unit capacitors 6a
It constitutes _{1 ~6a 4, 6b 1 ~6b 4} , 6c 1 ~6c 4 as one group. Note that, for convenience of explanation, only the + side of the inverter circuit has been described above, but the negative side of the inverter circuit, which is not shown, has the same configuration.

Here, paying attention to the commutation operation of the current source inverter, the output frequency upper limit value is obtained.
It is shown in (4).

[0007]

[Equation 1]

The variables are as follows. f _MAX
... output frequency upper limit value, T ... commutation period, T1 ... single flow period,
Tu ... overlap period, C ... commutation capacitance, L ... DC reactor inductance, Vm ... output voltage, I _DC ... DC current, theta ... load power factor angle.

[0009]

The upper limit of the output frequency in the current-type static variable frequency variable voltage power supply device is set as the main circuit constant according to the maximum rated output design condition. When is small, the output frequency upper limit value is lowered. Therefore, when a unit test or a light load operation of the electric motor 9 is performed, the output frequency upper limit value decreases due to the small load capacity, and there is a problem that the maximum rated rotation speed or the test or operation at the rated rotation speed is difficult. there were.

It is an object of the present invention to provide a static variable frequency variable voltage power supply device capable of changing the main circuit constant of a current source inverter circuit so that the maximum rated rotation speed can be achieved during a unit test of an electric motor. To do.

[0011]

In order to achieve the above object, a static variable frequency variable voltage power supply device according to a first aspect of the present invention is a static variable frequency variable voltage power supply device for driving an electric motor. It is characterized in that the commutation capacitors provided in the circuit are a plurality of unit capacitors, some of which are separated and are connected in parallel via a disconnector.

A static variable frequency variable voltage power supply device according to a second aspect of the present invention is a static variable frequency variable voltage power supply device for driving an electric motor, wherein a disconnecting switch is inserted in series with a commutation capacitor in a current source inverter circuit. It is characterized by connecting a parallel circuit of series commutation capacitors.

A static variable frequency variable voltage power supply device according to a third aspect of the present invention is a static variable frequency variable voltage power supply device for driving an electric motor, wherein the static variable frequency variable voltage power supply device is connected in parallel to a DC reactor torque torque generator inserted in a series circuit of a current source inverter. The series circuit of the DC reactor and the parallel disconnector is connected in parallel.

A static variable frequency variable voltage power supply device according to a fourth aspect of the present invention is a static variable frequency variable voltage power supply device for driving an electric motor, wherein two DC reactor torque torques are provided in a series circuit of a current type inverter and the two It is characterized in that a series-parallel switching disconnector of two DC reactor torque is inserted.

[0015]

According to the first aspect of the present invention, the capacitance of the commutation capacitor when the disconnecting and disconnecting switch is closed is such that the main capacitor of the inverter is sufficient to drive the motor having the maximum rated load capacity during normal load operation. The circuit constant is obtained. When the disconnecting / disconnecting switch is opened, some of the unit capacitors are disconnected and the capacitance of the commutation capacitor is reduced, so that the motor can be driven at the maximum rated speed even when the load is light, such as when using a motor alone. it can.

According to the second aspect of the present invention, during normal load operation, the insertion disconnecting switch is closed and the series commutation capacitor is short-circuited. Therefore, the commutation capacitor is an inverter sufficient for driving the motor of the maximum rated load. It becomes the capacitance that becomes the main circuit constant. When the insertion disconnector is opened, a series commutation capacitor and a commutation capacitor are connected in series to reduce the total electrostatic capacitance, and the motor should be driven at the maximum rated speed even under light load such as a single motor. You can

According to the third aspect of the present invention, during normal load operation, the parallel disconnector is opened and the inductance of the DC reactor in the DC circuit becomes a value sufficient to drive the motor having the rated load capacity.

When the parallel disconnector is closed, the total inductance of the direct current reactor in the direct current circuit is reduced by connecting the direct current reactor and the parallel direct current reactor in parallel. By connecting the parallel DC reactors in parallel to the reactor, the total inductance of the two DC reactors is reduced, and the electric motor can be driven at the maximum rated speed even under a light load.

When the two DC reactors are connected in series by the switching disconnector, the total inductance of the DC reactor has a value sufficient to drive the motor having the maximum rated load capacity. Further, when the switching disconnector is switched and the two DC reactors are connected in parallel, the total inductance of the DC reactor at this time is reduced, and the electric motor at light load can be driven at the maximum rated rotation speed.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings. It should be noted that the same components as those in the above-described conventional technique are designated by the same reference numerals, and detailed description thereof will be omitted. In the first embodiment, the thyristors 5a to 5c and the diode 7a are provided on the + side of the current source inverter circuit as shown in the main part configuration diagram of FIG.
Commutating capacitors 10a to 10c connected between 7 to 7c, each group consisting of four unit commutating capacitors 10a ₁ to 10c.
_{a 4, 10b 1 ~10b 4,} 10c 1 ~10c well as composed of _four, each commutation part of the unit commutation capacitor 10a in the capacitor _{10a~10c 1, 10b 1, 10c 1} , disconnect disconnector respectively 11a~ Configured by connecting via 11c.

Four unit commutation capacitors 10a _{1 each}
〜10a ₄ , 10b ₁ 〜 10b ₄ , 10c ₁ 〜 10c ₄ commutation capacitors 10a 〜 10c, the capacitance of the motor 9 is the rated load due to the inverter circuit transfer operation at the maximum rated speed. Is a possible value.

Further, the unit commutation capacitors 10a ₁ , 10b ₁ and 10c _{1 which} are separated from the respective commutation capacitors 10a to 10c by the disconnecting and disconnecting switches 11a to 11c are the remaining three unit commutation capacitors 10a ₂ to 10a ₂ . 10a ₄ , 10b _{2 to} 10b ₄ ,
Even if the main circuit constant of the inverter is changed by this capacitance and the direct current flowing under a light load is small, the output frequency upper limit value is set to the maximum rated rotation speed of the electric motor 9 by the electrostatic capacitance due to 10c _{2 to} 10c _4. Set the capacitance to match.

The positive side of the inverter circuit and the negative side of the inverter circuit (not shown) are connected to the commutation capacitor 5d.
.About.5f and the diodes 7d to 7f and the commutation capacitors and the disconnecting disconnecting switches have the same configuration, but the description will be omitted because it is redundant and only the + side circuit will be described.

Next, the operation of the above configuration will be described. In normal load operation, the disconnecting disconnectors 11a-11
kept closed to c, the unit commutation capacitor 10a of four each commutation capacitor 10a~10c each _{1 ~10a 4,} 10b ₁ ~
10b ₄ and 10c _{1 to} 10c ₄ are connected in parallel, and the capacitance is sufficient for the motor 9 to operate at the maximum rated rotation speed at the rated load.

A unit test of the electric motor 9 in a periodic inspection,
Or when performing light load operation, disconnecting disconnecting switch 11a-
11c to open the commutation capacitors 10a~10c from units commutation capacitor 10a _1, 10b _1, disconnect 10c _1, the commutation capacitor 10a~10c the unit commutation capacitor 10a ₂ 10 A ₄ respectively, 10b ₂ ~10b _4, 10c ₂ is formed by three ~10c _4.

As a result, each of the commutation capacitors 10a to 10c
Capacitance at the unit commutation capacitors 10a ₁ and 10b
_The output frequency upper limit is a value commensurate with the maximum rated rotation speed of the electric motor 9 even if the direct current flowing in the light load is small due to the reduction of the electrostatic capacity excluding ₁ and 10c ₁ and the change of the main circuit constant of the inverter. So that the electric motor 9
Even in the unit test and the light load operation, the electric motor 9 can be set to the maximum rated rotation speed or the like.

In the second embodiment, the + side of the current source inverter circuit is connected to the thyristors 5a ...
Each of the commutation capacitors 6a to 6c connected between 5c and the diodes 7a to 7c is connected in series with a parallel circuit of series commutation capacitors 12a to 12c and insertion disconnectors 13a to 13c.

[0028] Each commutation capacitor 6a~6c are both so easy to obtain a desired capacitance, respectively, for example of four units capacitors 6a ₁ ~6a _4, 6b ₁ ~
6b ₄ , 6c _{1 to} 6c ₄ are configured as one group, and the motor 9
Is a value that allows operation at the maximum rated rotational speed under rated load.

The serial commutation capacitors 12a-12c are
When the insertion disconnectors 13a to 13c are opened, they are in series with the respective commutation capacitors 6a to 6c, and the output frequency upper limit value at light load becomes an electrostatic capacity commensurate with the maximum rated rotation speed of the electric motor 9. The main circuit constant of the inverter is changed. In addition, each of the commutation capacitors 6a to 6c described above.
The same operation can be obtained even if each is a single unit commutation capacitor.

Further, the commutation capacitors 6d to 6f connected between the thyristors 5d to 5f and the diodes 7d to 7f on the + side of the inverter circuit and on the negative side of the target (not shown) are connected in series in the same manner as the + side. It is configured by connecting a parallel circuit of a current condenser and a disconnector in series.

As a function of the above construction, in a normal load operation, the insertion disconnecting switches 13a to 13c are closed and the series commutation capacitors 12a to 12c are short-circuited. This allows
Due to the capacitance of each of the commutation capacitors 6a to 6c, the main circuit constant of the inverter operates so that the electric motor 9 has a value capable of operating at the maximum rated rotation speed at the rated load.

Next, when performing a unit test of the electric motor 9 in a periodic inspection or the like, when the insertion disconnectors 13a to 13c are opened, the series commutation capacitors 12a to 12c are connected in series with the commutation capacitors 6a to 6c. Are connected. As a result, the total capacitance of the commutation capacitor is reduced, the main circuit constant of the inverter is changed accordingly, and the upper limit value of the output frequency at light load is set to a value commensurate with the maximum rated rotation speed of the electric motor 9. . Therefore, the unit test of the electric motor 9 can be performed at the maximum rated rotation speed.

In the third embodiment, as shown in the configuration diagram of the main part of FIG. 3, in parallel with the DC reactor 4 inserted in the DC circuit,
It is configured by connecting a series circuit of a parallel DC reactor 14 and a parallel disconnecting switch 15, and the other parts have the same configuration as in FIG.

The inductance of the DC reactor 4 is set to a value sufficient to drive the electric motor 9 at the rated rotation speed with the maximum rated load, and the inductance of the DC reactor maximum rating is in parallel with the DC reactor 4. Is lower than the inductance of the DC reactor 4 and is set to a value commensurate with the maximum rated rotation speed of the electric motor 9 at a light load.

The function of the above construction is to keep the parallel disconnector 15 open during normal load operation. Due to this, the reactor inductance of the DC circuit becomes a value suitable for driving at the rated rotation speed at the maximum rated load by the DC reactor 4, and the electric motor 9 is operated.

When a unit test of the electric motor 9 is carried out in a periodic inspection or the like, the parallel disconnector 15 is closed and the DC reactor 4 and the DC reactor maximum rating are connected in parallel. As a result, the total inductance is reduced compared to the case of the DC reactor 4 and has a value commensurate with the drive at the maximum rated rotation speed even under a light load. Therefore, the electric motor 9 can be operated alone at the maximum rated rotation speed. Can be done easily.

In the fourth embodiment, a DC reactor 16 and a DC reactor 17 are provided in a DC circuit, as shown in the block diagram of the main part of FIG.
The two are provided so that they can be switched to serial and parallel connection by the switching disconnector 18.

The DC reactor 16 and the DC reactor 17 have a total inductance in a series state which is sufficient to drive the electric motor 9 at the maximum rated load, and a total inductance in a parallel state when the series connection is made. Further, the upper limit value of the output frequency is set to a value commensurate with the maximum rated rotation speed when the electric load of the electric motor 9 is light.

As a function of the above configuration, in the normal load operation, the switching disconnector 18 brings the DC reactor 16 and the DC reactor 17 in series. As a result, the reactor inductance of the DC circuit becomes a value suitable for driving at the maximum rated load, and the electric motor 9 is operated.

When a unit test of the electric motor 9 is carried out in a periodic inspection or the like, the switching disconnector 18 brings the DC reactor 16 and the DC reactor 17 into a parallel state. As a result,
The total inductance is smaller than that in the series state, and is a value commensurate with driving the electric motor 9 at the maximum rated speed even under a light load. Therefore, the electric motor 9 alone can be operated at the maximum rated speed. , A unit test can be easily performed.

[0041]

As described above, according to the present invention, in a large-capacity, current-source static variable-frequency variable-voltage power supply device, the maximum rated rotation speed of the electric motor is maintained even in a light load condition such as a motor unit test at the time of regular point verification. Since it can be driven by, it is effective for checking the function and improving the reliability of a large electric motor.

[Brief description of drawings]

FIG. 1 is a main part configuration diagram of an inverter circuit according to a first embodiment of the present invention.

FIG. 2 is a main part configuration diagram of an inverter circuit according to a second embodiment of the present invention.

FIG. 3 is a main part configuration diagram of an inverter circuit according to a third embodiment of the present invention.

FIG. 4 is a main part configuration diagram of an inverter circuit according to a fourth embodiment of the present invention.

FIG. 5 is a configuration diagram of a conventional static power supply device.

FIG. 6 is a main part configuration diagram of an inverter circuit of a conventional static power supply device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... AC power supply, 2 ... Input transformer, 3a-3f ... Rectifier circuit component element, 4, 16, 17 ... DC reactor, 5a-5f
... thyristors, 6a~6f, 10a~10c ... commutation _{capacitor, 6a 1 ~6a 4, 6b 1} ~6b 4, 6c 1 ~6
c ₄ , 10a _{1 to} 10a ₄ , 10b _{1 to} 10b ₄ , 10c _{1 to} 10c
₄ ... Unit commutation capacitor, 7a-7f ... Diode, 8
... output transformer, 9 ... electric motor, 11a-11c ... disconnection disconnecting switch, 12a-12c ... series commutation capacitor, 13a-13c ... insertion disconnecting switch, 14 ... parallel DC reactor, 15 ... parallel disconnecting switch,
18 ... Switching disconnector.

Claims (4)

[Claims] 1. A static variable frequency variable voltage power supply device for driving an electric motor, wherein a commutation capacitor provided in a current source inverter circuit is a plurality of unit capacitors, and a part of which is cut off and connected in parallel via a disconnector. Characteristic static type variable frequency variable voltage power supply device. 2. A static variable frequency variable voltage power supply device for driving an electric motor, characterized in that a parallel circuit of an insertion disconnecting switch and a series commutation capacitor is connected to a current source inverter circuit in series with a commutation capacitor. Type variable frequency variable voltage power supply. 3. A static variable frequency variable voltage power supply device for driving an electric motor, wherein a series circuit of a parallel DC reactor and a parallel disconnector is connected in parallel to a DC reactor torque inserted in a series circuit of a current source inverter. Static type variable frequency variable voltage power supply device. 4. A static variable frequency variable voltage power supply device for driving an electric motor, wherein two direct current reactors and a series-parallel switching disconnecting switch for these two direct current torque tor are inserted in a series circuit of a current source inverter. Characteristic static type variable frequency variable voltage power supply device.