JPH0216664B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a switching element drive circuit that prevents arm short circuits of an inverter from occurring.

With the improvement in the performance of semiconductor switching elements such as thyristors, GTO thyristors (gate turn-off thyristors), and transistors, it is now possible to convert commercial AC power to DC, and then convert it back to AC again, making it possible to use AC power at any frequency. Static inverters using the forward and reverse conversion method have come to be widely used for driving induction motors (IMs).

An example of such an inverter is shown in FIG.

In the figure, 1 is a forward conversion unit for obtaining DC from commercial AC, 2 is an inverse conversion unit for obtaining 3-phase AC from DC, 3 is IM, 10 to 20 are diodes, 22 is a smoothing capacitor, and 30 to 40 are transistor,
Switching elements such as gate turn-off thyristors and 42 to 52 are freewheel diodes.

The diodes 10 to 20 rectify the input three-phase alternating current and supply it to the capacitor 22. Therefore,
A substantially smoothed DC voltage is obtained between the terminals of the capacitor 22.

The switching elements 30 to 40 are turned on and off by gate signals supplied from a switching control circuit (not shown), and convert the DC voltage appearing between the terminals of the capacitor 22 into a three-phase AC voltage, which is then applied to the IM3. supply By controlling the gate signal described above, the frequency and voltage of the three-phase AC supplied to IM3 can be arbitrarily controlled, and thereby the rotation speed of IM3 can be arbitrarily controlled while keeping the torque of IM3 constant. can do.

By the way, the inverse converter 2 of such an inverter
In , the first and second pairs are respectively
switching elements 30 and 32, 34 and 36, 3
8 and 40 are inserted in series between DC voltages +E and -E.

A series circuit consisting of such a pair of switching elements (for example, switching elements 30 and 32) is called an arm. Therefore, the inverter shown in Fig. 1 has three arms, and they are All are connected to a DC power supply.

However, the inverse conversion section 2 of such an inverter
As is clear from FIG. 1, if the first and second switching elements constituting each arm, for example 30 and 32, are conductive at the same time, a short circuit occurs between DC voltages +E and -E. This may cause a so-called arm short circuit, which may cause the protective device to operate or cause a major accident such as destruction of the switching element.

Therefore, in such an inverter,
The first pair forming the arm of the inverse conversion section
In order to avoid a situation in which the first and second switching elements become conductive at the same time, for example, as shown in FIG. 3
The switching control circuits 24 and 26 of 0 and 32 are provided independently, and as shown in FIG. 3, there is a non-overlapping period of about 20 to 100 μS between the conduction period of the first switching element 30 and the conduction period of the second switching element 32. Control is performed to provide t. Note that since the explanation here uses a transistor as an example of a switching element constituting each arm, the gate signal will also be explained below accordingly.
Therefore, in the waveform diagram of FIG. 3, I _B1 is the base current of the switching element 30, and I _B2 is the base current of the switching element 32.
Each represents the base current of .

However, even if independent switching control circuits 24 and 26 are provided for the first and second switching elements of each arm and a non-overlapping period t is provided between the conduction periods, the third
The base current sometimes flows at the timing shown by the broken line in the figure, making it impossible to completely prevent arm short circuits.

The following two points are thought to be the cause of this.

First, one problem is noise intrusion into the respective switching control circuits 24 and 26, and the other problem is the capacitance that exists between the control electrodes and output electrodes of the switching elements 30 and 32, such as the base capacitance in the case of transistors. Capacity between collectors
Because of C _0b , when the potential change between these electrodes is sudden, a displacement current determined by the product of this potential change dv/dt and the capacitance C _0b flows, resulting in a displacement current of several μS as shown by the broken line in Figure 3.
This results in an unnecessary base current with a length of several tens of microseconds.

Therefore, conventionally, a circuit as shown in FIG. 4 has been used as these switching control circuits 24 and 26.

In Fig. 4, PC _a and PC _b are light receiving elements consisting of a light emitting element such as a light emitting diode and a phototransistor, which constitute a so-called optical coupling control type gate circuit such as a photocoupler, and the control signal is transmitted to the light emitting element CP. When supplied to _a , the light receiving element
CP _b turns on and transistor TR ₁ becomes a transistor
Turn on TR ₂ and apply power to switching element 30.
Supply base current I _B1 from E ₁ .

When the control signal is not supplied, the transistor _TR3 is turned on to prevent the base current I _B1 from flowing through the switching element 30.

A capacitor C is connected in parallel between the base and emitter of the switching element 30 to bypass unnecessary base current from flowing into the switching element 30.

However, in the conventional example shown in FIG. 4, the capacitor C needs to have sufficiently low transient impedance and must be provided sufficiently close to the switching element 30, making it easy to increase the size of the capacitor and make installation difficult. This becomes difficult and costs increase. Furthermore, the installation of the capacitor C lowers the switching speed of the switching element 30, resulting in disadvantages such as a decrease in performance such as a tendency to increase temperature.

FIG. 5 shows another conventional example in which a power source _E2 is provided in addition to the power source _E1 , and the base of the switching element 30 is always reverse biased through a resistor R. At times other than when the light receiving element CP _b is turned on and the base current I _B1 is supplied from the power source E ₁ to the switching element 30 via the transistor TR ₂ , the switching element 30
The base of the is kept at a negative potential.

However, in the conventional example shown in FIG. 4, a DC power source _E2 is also required in addition to the DC power source _E1 , so that the device tends to be large-sized and the cost increases significantly.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a low-cost switching element drive circuit that can reliably prevent arm short circuits with a simple configuration and eliminates the drawbacks of the prior art described above.

In order to achieve this object, the present invention provides an interlock function for controlling conduction of one of the first and second switching elements constituting the arm and preventing conduction of the other. A set of two optically coupled controlled gate circuits is used for each switching element, and two sets are used for each arm, and the light emitting elements of each set of optically coupled controlled gate circuits are connected in series to generate a conduction control signal for each switching element. is supplied, one output of each set of optically coupled controlled gate circuits controls conduction of one switching element, and the other output prevents conduction of the other switching element. shall be.

Embodiments of the switching element drive circuit according to the present invention will be described below with reference to the drawings.

FIG. 6 shows an embodiment of the present invention, and FIG.
Parts that are the same or equivalent to those in the figures are given the same reference numerals.

In this figure 6, CP _a 3, CP _b 3, and
CP _a 4 and CP _b 4 are a light emitting element and a light receiving element of a photocoupler, respectively. Note that the switching control circuits 24 and 26 are the same as the conventional example shown in FIG.
The capacitor C is not provided, and the light emitting elements for the light receiving element CP _b are shown as CP _a 1 and CP _a 2, respectively.
The light emitting elements CP _a 1 and CP _a 3 are connected in series to form a first control signal input circuit, and this circuit is connected to the switching element 3 at predetermined timings.
The light emitting elements CP _a 2 and CP _a 4 are also connected in series to form a second control signal input circuit. It is configured such that a control signal for introducing the switching element 32 is supplied at predetermined timings.

Next, the operation of this embodiment will be explained.

At the timing when the switching element 30 should be made conductive, a control signal is supplied to CP _a 1, and the light emitting element CP _a
The light receiving element in the control circuit 24 receives the optical signal from 1.
CP _b (Fig. 4) turns on, switching element 30
A base current I _B1 is supplied to the base current I B1 and the base current I B1 is controlled to be conductive.

Furthermore, when the timing to make the switching element 32 conductive is reached, a control signal is supplied to the light emitting element CP _a 2, and at this time, the base current I _B2 is supplied from the control circuit 26 to the switching element 32 to control it to the conductive state.

Since the light emitting element CP _a 1 is connected in series with the light emitting element CP _a 3 of a different photocoupler, the light emitting element CP _a 3 also emits light at the timing when the switching element 30 should be made conductive. The light turns on the light receiving element CP _b 3 connected in parallel between the base and emitter of the other switching element 32 of the arm.

Similarly, at the timing when the switching element 32 should be made conductive, the light emitting element CP _a 4 of another photocoupler connected in series with the light emitting element CP _a 2
also emit light, and as a result, switching element 3
The light receiving element CP _b 4 connected in parallel between the base and emitter of 0 is turned on.

That is, in this embodiment, when a control signal to make the first switching element 30 constituting the arm conductive is supplied to it, the input circuit between the base and emitter of the second switching element 32 is almost in a short-circuited state. retained, as well as
When a control signal is applied to the second switching element 32 to make it conductive, an interlock function is provided which serves to bring about a short circuit in the input circuit between the base and emitter of the first switching element 30. This means that

Therefore, according to this embodiment, when one of the paired switching elements constituting the arm, for example, the first switching element 30, is conductive, the other switching element, the second switching element, is electrically conductive. Whatever voltage is induced between _the base and emitter of the second
There is no possibility that the first switching element 32 becomes conductive, and similarly, there is no possibility that the first switching element 30 becomes conductive while the second switching element 32 is conductive. arm short circuit can be completely prevented.

According to this embodiment, the interlock function described above is provided using two sets of photocouplers consisting of the light emitting elements CP _a 3 and CP _a 4 and the light receiving elements CP _b 3 and CP _b 4, respectively. Electrical isolation can be easily achieved between the input circuits of each switching control circuit 24, 26 and the base/emitter input circuits of each switching element 30, 32, and the circuit configuration is simplified. is obtained.

Further, in the above embodiment, the photocoupler's light receiving elements CP _b 3 and CP _b 4 directly connect the switching element 30,
The base and emitter of 32 are short-circuited, but if you want to further lower the impedance at the time of short-circuit, these light-receiving elements CP _b 3, CP _b 4
Other switching elements controlled by the output of the switching elements 30 and 32 may be provided to bypass the bases and emitters of the switching elements 30 and 32.

Furthermore, in the above embodiment, only one of the arms in the inverter's inverter is explained, but this is to simplify the explanation, and in reality, it is necessary to provide all the arms in the inverter's inverter. Needless to say, it is desirable, for example, in the inverter shown in Fig. 1, not only the U-phase arm but also the V-phase and W
phase arms, i.e. switching elements 34, 36,
It goes without saying that the drive circuits 38 and 40 also need to be provided.

As explained above, according to the present invention, an interlock function is provided in which a conduction control signal for each of the first and second switching elements constituting the arm actively prevents conduction of the other switching element. At the same time, the light-emitting elements of the optical coupling control type gate circuit for this purpose are connected in series, one for controlling conduction of one switching element and one for controlling conduction blocking of the other switching element, and controlling one switching element to conduct. Since it is configured to operate in common by a signal, there is no time lag in the interlock operation, and the interlock function is reliable.
For example, in FIG. 6, if the issuing element CP _a 3 or CP _a 4 of one of the optical coupling control type gate circuits is disconnected,
Since the other light emitting element CP _a 1 or CP _a 2 also ceases to emit light, a fail-safe in the event of an abnormality is automatically provided, and high reliability can be easily obtained.

Moreover, as a result, a control signal input circuit consisting of light emitting elements CP _a 1 and CP _a 3 and a control signal input circuit consisting of light emitting elements CP _a 2 and CP _a
If the control signal is input to both of the control signal input circuits consisting of 4 and 32 at the same time,
Since any switching element is prevented from conducting, a complete fail-safe function against an arm short circuit is provided at this time as well, and therefore, according to the present invention, sufficient safety is maintained. A switching element drive circuit that can easily obtain excellent reliability, eliminate the drawbacks of the prior art, and reliably prevent arm short circuits with a simple configuration can be provided at low cost.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing an example of an inverter used for driving an AC motor, Fig. 2 is a block diagram for explaining its control operation, Fig. 3 is a waveform diagram for explaining its operation, and Fig. 4 is a circuit diagram showing an example of an inverter used for driving an AC motor. 5 is a circuit diagram showing another conventional example of a control circuit, and FIG. 6 is a circuit diagram showing an embodiment of a switching element drive circuit according to the present invention. . 24, 26... switching control circuit, 30,
32...First and second switching elements constituting the arm, CP _a 1, CP _a 2, CP a 3, CP _{a 4} ... Photocoupler light emitting element, CP _b 1, CP _b 2, CP _b 3,
CP _b 4...photocoupler light receiving element.

Claims (1)

[Claims] 1. A first optically coupled controlled gate circuit having at least one arm between a DC power supply and comprising first and second switching elements connected in series, and supplying a conduction signal to the first switching element; a second switching element for supplying a conductive signal to a second switching element;
an optically coupled controlled gate circuit; and a third optically coupled controlled gate circuit that supplies a conduction blocking signal to the second switching element in response to generation of a control signal for making the first switching element conductive. ,
an inverter switching element drive circuit comprising: a fourth optically coupled controlled gate circuit that supplies a conduction blocking signal to the first switching element in response to generation of a control signal for rendering the second switching element conductive; A first light-emitting element in which a light-emitting element of the first optical coupling control type gate circuit and a light-emitting element of the third optical coupling control type gate circuit are connected in series.
and a second control signal input circuit in which a light emitting element of the second optical coupling control type gate circuit and a light emitting element of the fourth optical coupling control type gate circuit are connected in series. , supplies a control signal for making the first switching element conductive to the first control signal input circuit;
A switching element drive circuit for an inverter, characterized in that the switching element drive circuit for an inverter is configured to supply a control signal for making the second switching element conductive to the control signal input circuit.