JPH0787703B2 - Inverter output voltage detection circuit - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an output voltage detection circuit for an inverter, and more particularly to a phase voltage detection circuit for giving to an upper and lower arm short circuit prevention time correction circuit for the inverter. .

[Conventional technology]

FIG. 6 shows a configuration diagram of a pulse width modulation (hereinafter, referred to as PWM) inverter having an upper and lower arm short circuit prevention time (hereinafter, referred to as TD) correction circuit for driving a motor such as an induction machine or a synchronous machine. in the figure, the inverter output element comprising a transistor ^{(1U +), (1U -} ), (1V +), (1V -), (1
^{W +), (1W -)} , which in parallel connected backward diode ^{(2U +), (2U -} ), (2V +), (2V -), (2W +), (2
W ^-), and bass amp ^{(3U +), (3U -} ), (3V +),
(3V ⁻ ), (3W ⁺ ), (3W ⁻ ) are provided, and the voltage and frequency applied to the motor (4) are controlled by turning on and off the output element.

Then, (5U), (5V), and (5W) are U-phase, V-phase, and W-phase voltage detection circuits that detect the U-, V-, and W-phase output voltages, and (6) is the above-mentioned phase-voltage detection circuit. Circuit (5U), (5V),
Based on the detection signal from (5W) and the pattern signal from the PWM generation circuit (7), each of the base amplifiers (3U ⁺ ), (3
^{U -), (3V +)} , (3V -), (3W +), (3W - control signal)
^{U +, U -, V +} , V -, W +, W - is a TD correction circuit for delivering.

Note that V _DC indicates a direct current.

In the above configuration, the output terminal ^{(1U +), (1U -} ), (1V
⁺ ), (1V ⁻ ), (1W ⁺ ), (1W ⁻ ) can be supplied with a variable voltage variable frequency controlled power supply voltage to the motor (4) by on / off control.

However, where, for example, the output device ^{(1U +), (1U -} ) I alternately turned on and off. However, the output device so destroying the element cause the upper and lower short-circuit and on at the same time ^{(1U +), (1U -} )
During the ON period of, it is necessary to take some time TD for preventing upper and lower arm short circuits.

However, since the upper and lower arms of the output element are turned off during the TD period, the terminals U, V, W of the motor (4) are open, and the terminal voltage of the motor becomes uncontrollable during this period.

As a result, unstable development occurs in the motor (4), and adverse effects such as torque ripple occur.

Therefore, as a conventional method, each phase voltage detection circuit (5U), (5V), (5W) detects each phase voltage of U, V, W in the TD period, and this detection result and PWM pattern creation The required PWM pattern output from the circuit (7) is matched and the TD correction circuit (6) creates a pattern in which the dead time of the TD and the corrected pattern are created. The resulting pattern is used as the base amplifier (3U ^{+ ), (3U -), (} 3V +), (3V -), (3
W ^+), (3W ^- control signals U ^+, U ^{to) -, V +, V -} , W +, W - to have is taken way that this adverse effect of TD by is removed.

FIG. 7 (a) shows an example of a conventionally used phase voltage detection circuit. In the figure, a U-phase voltage detection circuit (5U) is provided with a resistor R, a photocoupler at the output end of the main circuit element of the inverter.
PC is connected in series and equipped with control voltage dc.
It is adapted to detect whether the phase output voltage is at a positive or negative potential with respect to the main circuit bus voltage, electrically insulate the signal, and transmit it to the TD correction circuit (6).

Thus, for example, when the motor input terminal U is H (high), a current flows to the input of the photocoupler PC through the resistor R and the photocoupler is turned on. And now, during the period of TD, the output element (1U
^+), (1U ^-) because co-off, its orientation by reverse diodes (2U ⁺⁾ or (2U of motor current when ^-) is turned on and if the motor current is a direction of view the 7 (b) The reverse diode (2U ⁺ ) is turned on and the output terminal U becomes H.

[Problems to be Solved by the Invention]

Since the conventional circuit is configured as described above, the resistor R
However, there is a drawback in that it consumes a large amount of electricity and requires a large wattage resistance.

That is, the output element (1U ^{+), -} the duty (1U)
Assuming 50%, the power consumption W of the resistor R is Becomes

For example, in the case of an AC200V inverter, V _DC is usually 280
If, for example, 20 mA is applied to the photocoupler PC in [v], Is required.

At this time, Is very large. At this time, V _DC may rise up to 400V during motor regeneration. Becomes

Normally, it is necessary to add a resistor with a W number that is about four times the power consumption with a margin, so the W number of the resistor R is 5.7 x per phase.
4 = 22.8 [W], which is a huge amount.

It is only necessary to reduce the input current of the photocoupler PC, but the cheap high-speed photocoupler cannot do so because the CTR (current transfer ratio) of the photocoupler is small. There are also high-speed photocouplers with a small input current and a very short TD time, but they are expensive and vulnerable to noise.

The present invention has been made to solve the above problems, and an object of the present invention is to obtain an output voltage detection circuit which has low resistance power consumption and is resistant to fluctuations in _VDC and noise.

[Means for Solving the Problems]

The output voltage detection circuit of the inverter according to the present invention has a resistor, a reverse blocking diode, and an insulation transmission means connected in series to each phase output terminal of the inverter main circuit element, and at least as a voltage source of the series connection body of the inverter. Equipped with a common power supply common to each phase connected to one end of DC current,
A voltage signal is obtained from the insulation transmission means for each phase.

In addition, an output voltage detection circuit of an inverter according to another invention directly connects a resistor, a reverse blocking diode, and an insulation transmission means to each phase output terminal of the inverter main circuit element,
As a voltage source of this series connection body, at least one end of the DC power source of the inverter is connected, and a common power source that is common to each phase and shared by the base amplifier power source of the transistors of the lower arms that configure the inverter is provided. A voltage signal is obtained from the insulation transmission means for each phase.

[Work]

In the output voltage detection circuit of the inverter of the present invention,
When the voltage signal is output by the insulation transfer means, the current from the voltage source flows to the reverse diode of the output element through the insulation transfer means, the reverse blocking diode and the resistor, the power consumption in the resistor is small, and the DC power supply V _It is resistant to _DC fluctuations, and has at least three terminals to be detected by providing a common power source for each phase, which is connected to at least one end of the DC power source of the inverter, as the voltage source. It can be shared by a single voltage source without having to prepare for each phase, and by judging from the output of each phase insulation transmission means based on the operation mode of the inverter, the power supply abnormality of the common power supply, the interruption of the inverter main circuit element, etc. Abnormality can be detected promptly.

In an output voltage detection circuit for an inverter according to another invention, a common power source shared by each phase as a voltage source of a series connection body and a common power source shared by the base amplifier power sources of the transistors of the lower arms forming the inverter are used. By doing so, it is not necessary to provide a base amplifier power source for each transistor of each lower arm, and U, V, and W phases can be shared, and the power source can be determined by judging from the output of the insulation transmission means based on the operation mode of the inverter. It is possible to promptly detect an abnormality, such as an interruption of the inverter main circuit element, and especially to prevent the transistor in the lower arm from being destroyed when the base amplifier power supply is abnormally lowered.

〔Example〕

 Hereinafter, the prerequisite technique of the present invention will be described with reference to the drawings.

1 (a) and 1 (b) are the embodiments shown corresponding to FIGS. 7 (a) and 7 (b), and the same reference numerals indicate the same parts. In FIGS. 1 (a) and 1 (b), a U-phase voltage detection circuit (5U) as an output voltage detection circuit includes a resistor R, a reverse blocking diode RD, and insulation transmission to an output terminal U of a main circuit element of an inverter. A photocoupler PC as a means and a voltage source V _5U are connected in series, and a voltage signal is obtained from the photocoupler PC. In addition, E shows a DC power supply.

In the above configuration, when the output terminal U is L (low), that is, an output element (1U ^-) is on or the reverse diode (2
When U ⁻ ) is on, current flows through the reverse blocking diode RD and the resistor R to the photocoupler PC by the voltage source V _5U , and the photocoupler PC is turned on.

On the other hand, when the output terminal U is H (high), it is blocked by the reverse blocking diode RD, so that no current flows in the photocoupler PC. Because it take some large voltage compared to the saturation voltage of the output element ^- the voltage of the voltage source V _5U output element (1U) can be shared based amplifier power (1U ^{- -)} base amplifiers (3U). For example V _5U = 8V, the output element (1U ^-) and the saturation voltage of 1 v, the input voltage of the photocoupler PC 1.5V, as the diode drop of the reverse blocking diode RD 1.5V, when the flow 20 mA, Becomes

At this time, the number W of R is set to 1/2 the duty. Becomes (V _R is the voltage across R when the output U is L) This value is actually higher than W = 5.7 [W] in the conventional circuit.
It becomes 0.7%. Also, the input current of the photocoupler and the power consumption of the resistor do not depend on the value of V _DC .

Further, the voltage source V _5U passes bass amplifier described above ^- it is not necessary to newly provide if sharing the power of (3U).

Incidentally, at the output U when the TD period L (low) and the output element (1U ^-) reverse diode (2U ^-) is When on, the current from the voltage source V _5U reverse diode (2U ^- ) to seems to be blocked, usually, the motor current, i.e. reverse diode (2U ^-) to flow current output terminal U is sufficiently large compared to about photocoupler current mA several amperes or more at L (low), and the output element (2U ^-) reverse diode is on (the output element (1U ^-) is off) sufficient current flows (FIG. 1 the photocoupler PC as long as U is L (low) even when the (See (b)).

Note that FIG. 2 is a circuit using a pulse transformer T instead of a photocoupler as the insulation transmission means, and in this embodiment, the same effect as that of the above embodiment can be expected.

Further, FIG. 3 shows that the common power source V _{5U is connected} to the voltage source V _5U of FIG.
This is a circuit using _O. By doing so, no special power supply is required for the voltage source V _5U , and it is shared with the base amplifier power supply of the transistor on each lower arm side that constitutes the inverter, and the base for each transistor of each lower arm is used. It is not necessary to have an amplifier power supply, and U, V, and W phases can be shared, and a common power supply V _O
Since the negative side of is connected to the N bus, it can be shared by a single voltage source of V _O even though there are 3 terminals for detection.

In principle, the U terminal is L (low) as described above.
When the voltage goes down to near the potential of the N bus, current flows from the positive end of the common power supply to each output end of the inverter, and the light emitting diode of the photocoupler PC and the reverse blocking diode RD respectively.
Then, the photo coupler corresponding to the U phase is turned on, and it is detected that the U phase is L (low).

Further, in the case of the inverter operation, the output terminals of the respective phases do not become H (high) at the same time during the normal operation of performing the TD correction. In other words, the photocoupler PC for each phase cannot be turned off at the same time. Therefore, for example, if the common power supply V _O drops abnormally, the photocoupler PC of each phase simultaneously turns off,
By obtaining the logical product of the outputs of the photocoupler PC of each phase by the TD correction circuit 6, it is possible to immediately determine the abnormal decrease of the common power supply V _O , and by determining from the output of the photocoupler PC based on the operation mode of the inverter, the common Abnormalities such as power supply abnormality of the power supply V _O and base cutoff of the transistor can be detected promptly, and, for example, when the power supply of the common power supply V _O is lowered, the base amplifier power supply is lowered to cause insufficient base drive current to the transistor. If it is driven in that state, the transistor will continue to be in the active state and will overheat, resulting in destruction.
It is possible to protect the transistor from destruction by judging from the output of.

Further, FIG. 4 shows that when the positive end of the common power supply V _O is connected to the P bus and U, V, and W become H (high), current flows from each output end of the inverter to the negative end of the common power supply. It is configured such that a current flows through the light emitting diode, the reverse blocking diode RD and the resistor R of each photocoupler PC, and the principle is the same as in FIG. Furthermore, the fifth
The figure shows a case where the common power source V _{O in} FIGS. 3 and 4 is created by dividing the DC bus voltage by the capacitors C ₁ and C ₂ .
This has the advantage that the separate power supply V _O is unnecessary.

[Effects of the Invention] As described above, according to the present invention, a resistor, a reverse blocking diode, and an insulation transfer means are connected in series to each phase output terminal of an inverter main circuit element, and a voltage source of this series connection body is used. Since at least one common power source connected to one end of the DC power source of the inverter is provided and a voltage signal is obtained from the insulation transmission means for each phase, the resistance heat generation is small and the DC bus voltage is high. The output voltage detection circuit resistant to noise is obtained without the characteristics (heat generation of resistance, input current of insulation transmission means, etc.) being influenced by the fluctuation of each, and at least one end of the DC power source of the inverter is connected as the voltage source. By equipping the phases with a common power supply,
Although there are terminals to be detected for each phase, it can be shared by a single voltage source without having to be provided for each phase, and by judging from the output of each phase insulation transmission means based on the operation mode of the inverter, There is an effect that it is possible to promptly detect an abnormality such as a power supply abnormality of the common power supply and an interruption of the inverter main circuit element.

In an output voltage detection circuit for an inverter according to another invention, a common power source shared by each phase as a voltage source of a series connection body and a common power source shared by the base amplifier power sources of the transistors of the lower arms forming the inverter are used. By doing so, it is not necessary to provide a base amplifier power source for each transistor of each lower arm, and U, V, and W phases can be shared, and the power source can be determined by judging from the output of the insulation transmission means based on the operation mode of the inverter. It is possible to quickly detect an abnormality, such as an interruption of the inverter main circuit element, and in particular, it is possible to prevent the transistor in the lower arm from being destroyed when the base amplifier power supply is abnormally lowered.

[Brief description of drawings]

FIGS. 1 (a) and 1 (b) are a block diagram and an explanatory diagram for explaining the premise technique of the present invention, FIGS. 2 to 5 are block diagrams showing respective embodiments, and FIG. 6 shows a TD correction circuit. FIG. 7 (a) and FIG. 7 (b) are configuration diagrams of a PWM inverter having the conventional configuration diagram and explanatory diagrams corresponding to FIGS. 1 (a) and 1 (b). In the ^{figure, (1U +), (1U} -), (1V +), (1V -), (1
^{W +), (1W -)} , the output element constituting the inverter, U
Is an output terminal, (5U) is a U-phase voltage detection circuit, R is a resistor, RD is a reverse blocking diode, PC is a photocoupler, V _5U is a voltage source, T
Is a pulse transformer. In each figure, the same reference numerals indicate the same or corresponding parts.

Claims (2)

[Claims] 1. A method for detecting whether an output voltage of each phase of an inverter is at a positive or negative potential with respect to a neutral point of a main circuit bus voltage, and transmitting the signal electrically isolated. In the output voltage detection circuit of the inverter, a resistor, a reverse blocking diode, and an insulation transfer means are connected in series to each phase output terminal of the inverter main circuit element, and at least one end of the DC power supply of the inverter is used as a voltage source of the series connection body. An output voltage detection circuit for an inverter, characterized in that a common power supply is provided for each phase connected to each phase and a voltage signal is obtained from the insulation transmission means for each phase. 2. It is detected whether the output voltage of each phase of the inverter is at a positive or negative potential with respect to the neutral point of the main circuit bus voltage, and the signal is electrically isolated and transmitted. In the output voltage detection circuit of the inverter, a resistor, a reverse blocking diode, and an insulation transfer means are connected in series to each phase output terminal of the inverter main circuit element, and at least one end of the DC power supply of the inverter is used as a voltage source of the series connection body. And a common power supply common to each phase and shared by the base amplifier power supplies of the transistors of the lower arms that form the inverter, and obtain a voltage signal from the insulation transfer means for each phase. Inverter output voltage detection circuit.