JPS609378A - Inverter device - Google Patents

Abstract

PURPOSE:To enhance the power conversion efficiency by discharging the charge of a snubber capacitor through a reactor between positive and negative arm elements, thereby alleviating the di/dt duty of a self-extinguishing type switching element. CONSTITUTION:A 3-phase inverter has arms X, Y, Z of the respective phases. Snubbers 5U, 5X have snubber capacitors 51u, 51x and diodes 52u, 52x connected in series with the condensers. The anode side of the diode 52u of the snubber 5U and the cathode side of the diode 52x of the snubber 5X are connected through a diode circuit 6. The charges of the capacitors 51u, 52u are discharged through reactors 2U, 2X between the positive and negative arm elements.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an inverter device using a self-extinguishing switching element as an arm element.

Conventionally, there has been an inverter device of this type as shown in FIG. FIG. 1 is a circuit diagram showing an inverter constructed by bridge-connecting conventional self-extinguishing switching elements. In the figure, X.

Y and Z are arms representing one phase of a three-phase inverter, and the details thereof are shown as a representative X arm. P.

N is the positive pole and negative pole of the DC power supply, and IU and IX are gate turn-off transistors (hereinafter abbreviated as GTO), which are arm elements consisting of self-extinguishing switching elements, so that they alternately turn on and off. receives an on-gate signal. 2U and 2X are reactors, which are connected in series and inserted between GTOIU and GTOIX. au and 3x are feedback diodes, and the feedback diode 3U is connected in parallel to the series connection path of GTOIU, each reactor 2U and 2X, and the feedback diode 3X is connected to the series connection path of GTOxX, each reactor 2U and 2X. connected in parallel to the 4U and 4X are GTOIU and GTOI respectively
X snubber, snubber 4U is snubber capacitor 4
1u, diode 42u, resistor 43u, GTO
The snubber 4X is connected in parallel to the IU, and consists of a snubber capacitor 41x, a diode 42x, and a resistor 43x, and 1 and 0, which are connected in parallel to the GTOIX, are AC output terminals, and are connected to the reactors 2U and 2X. drawn from the point.

Next, the operation of the inverter shown in FIG. 1 will be explained with reference to FIG. 2. FIG. 2 is an operation waveform diagram of each part of the inverter shown in FIG. 1. In Fig. 2, Tu is the on-period of GTOIU, Tx is the on-period of GTOIX, Iw is the load current flowing to the load (in this example, the slow phase load), Iu and Ix are o'roiu and GTO, respectively.
The current flowing in IX, Iud, Ixd are the current flowing in feedback diode 3U and 3X, Vuc, Vx, respectively.
c is the voltage of the snubber capacitors 41u and 41X, respectively.

Now time 1. It is assumed that G'l'01U is turned on immediately before , and load current Iw is supplied to a load (not shown) through reactor 2U and AC output terminal U.

When GTOIU turns off at time t1, G'
The current 1u of l'01U flows to the snubber 4U, and the snubber capacitor 41u is charged (!: Feedback diode 3X is turned on, and the load current 1w flows through it. GTol
Immediately after time 11, X is given an on-game] signal,
The charge stored in the snubber capacitor 41x is transferred to the resistor 4
3x, and after this lightning discharge ends, time t
2 and the polarity of the load currents J and w is reversed, the feedback diode 3X comes to block the load current Iw, and the GT
Load current IW begins to flow through OIX. Thus,
AC' power is taken out from the AC output terminal U.

Conventional inverters are configured as described above11, so
Since the 111 load stored in the snubber capacitor is discharged through the resistor, there is a disadvantage that the OTO's di/di debt becomes high, and the charging energy is consumed by the snubber resistor, resulting in poor power conversion efficiency. There were drawbacks.

This invention was made in order to eliminate the drawbacks of the conventional ones as described in -F. In an inverter in which a self-extinguishing switching element is used as an arm element and a reactor is provided in each of the positive and negative arm elements, a snubber capacitor and a reactor are provided in each of the positive and negative arm elements. A snubber consisting of series-connected diodes is connected in parallel to each of the positive and negative arm elements, and the snubber capacitor side of the diode of each snubber is connected to each diode through a forward diode circuit. ,
A plurality of arms are provided by inserting current transformers into the diode circuit, the secondary windings of the current transformers of each arm are connected in series, and each series connection point is connected to a direct current source. It has a configuration in which it is connected to the AC terminal of a diode bridge circuit that is bridge-connected to In addition to being able to significantly increase the in/s
The purpose is to provide a data center.

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 3 is a circuit diagram showing an in/sl-output device which is an embodiment of the present invention. In the figure, X, Y, and Z are each arm indicating one phase of a three-phase inverter device, and the details are represented by the X arm, and the same parts as in Figure 1 are indicated using the same symbols. Yes, the detailed explanation will be omitted.

5U is a snubber capacitor 510
and a diode 521.1 connected in series to this, and connected in parallel to the GTOIU. 5X is a snubber, which consists of a snubber capacitor 51X and a tie connected in series with it, and a tie 52x, which is connected in parallel to GTOIX. diode 52x
The power ° node side is connected via a diode circuit 6,
I'm in A1. This diode circuit 6 is inserted 11 with its J-sode side facing the anode side of the diode 521m. 7 is a current transformer inserted into the diode circuit 6, and both terminals 7a of the secondary winding of the current transformer 7.

7b is connected to the positive &P of the DC power supply through diodes 8a and 8b, respectively, and
, 8e are connected to the negative electrode Nic 1- of the DC source 1 source. Similarly, the secondary windings of the Y-arm current transformers are connected to the positive pole P of the DC power supply through diodes 8b and 8c, respectively, and to the negative pole N of the DC power supply through diodes 8e and 8f, respectively. There is. Similarly, the secondary windings of the Z-arm current transformer are connected to diodes 8a and 8a, respectively.
It is connected to the positive pole P of the DC power supply via 8c, and to the negative pole N of the DC power supply through diodes 8d and 8f, respectively. Each of the diodes 8a and 5 described above
b.

8c, 8d, 8e, and 8f are connected to form a diode bridge circuit forming a three-phase bridge circuit.

Next, the operation of the inverter shown in FIG. 3 will be explained with reference to FIG. 4. FIG. 4 is an operation waveform diagram of each part of the inverter device of FIG. 3. In FIG. 4, In is a diode circuit 6. The current flowing through the current transformer 7 is shown. Now, at time t1, when the GTOIU, which has been on until now, is turned off, the iQ flow flowing through the GTOIU is transferred to the snubber 5U, and the snubber capacitor 51u is charged. At this time, the charge of the snubber capacitor 51x of the snubber 5X is released through the diode circuit 6 - current transformer 7 - diode 5211 - reactor 2U - AC output terminal U to the load shown in the figure. . Immediately after time t1, when J'l'01X is turned on, the charge of the snubber capacitor 51X passes through the diode circuit 6 - the current flow device 7 - the diode 5211 - the reactor 2U - the reactor I/L 2X - the GTOIX. The discharge current of the snubber capacitor 5] and ,
7t1. - The diodes 8b and 8d are caused by the pressure that occurs when the excitation current of the current flow device 7 drops to zero.
is turned on, and the voltage between both terminals 7a and 7b of the secondary winding of the current transformer 7 is clamped to the voltage between the positive terminal P and the negative terminal N of the DC power supply. Speed up the reset. When the charging of the snubber capacitor 510 is completed, the load current Iw flows through the feedback terminal (X-reactor 2U-AC output terminal U).
When the polarity of the load ytr and current bv is reversed at time t2, the feedback diode 3X is turned off. When turned on, the discharge path including the series reactors 2U and 2X is closed, and the discharge current of the snubber capacitor flows through this discharge path (JTO's di/dt liability is reduced. When you turn off,
The charge on the snubber capacitor is transferred to the diode circuit 6. partner(
The current flows to the load through one of the snubber diode and reactor of )TO, so if the turn-on period of GTOIU and ()TOIX are separated by an interval and there is a period when both are off at the same time, the power conversion Furthermore, when the snubber capacitor is discharged, the discharge current flows from the secondary side of the current transformer 7 to the respective diodes 8a.

Since it will be returned to the DC power supply side through 8e,
Power conversion efficiency is further improved.

FIG. 5 is a circuit diagram showing an inverter device according to another embodiment of the present invention, in which each feedback diode 3U.

3X are G'll"01LJ and u'l'oI respectively
In that it is connected in antiparallel to X, the third
This is different from the embodiment shown in the figure. Also in the embodiment shown in FIG. 5, as shown in the operation waveform diagram of FIG. 6, for example,
When the GTOIU turns off, the snubber capacitor 51
0 is charged, and the y+1° load of the snubber capacitor 51X is the diode circuit 6 - current transformer 7 - diode 52u -
') Flowing through the axle 2U to a load (not shown) 2,
When this charging/discharging is completed, the load current Iw flows through the feedback diode 3X, the quasiode 52x, the quaiode circuit 6, the current transformer 7, the diode 52u, and the reactor 2U. Furthermore, when G'l"01X is turned on, the charge C1 of the snubber capacitor 51x is
, 2X and discharge.

In each of the above embodiments, a ψ1 combination using a three-phase bridge circuit was explained as a diode bridge circuit, but even if a large number of these are connected in parallel to form a multiphase inverter circuit, the same result as in each of the above embodiments will be achieved. It has the effect of

Furthermore, in each of the embodiments described above, the charging energy of the snubber capacitor Jlj4 taken out via the current transformer 7 may be returned to another DC power source.

Further, the self-extinguishing switching element in each of the above embodiments may be any switching element having self-extinguishing ability, such as a transistor.

As described above, according to the inverter device of the present invention, the resistance of the snubber of the positive and negative rotor arm elements having self-extinguishing switching elements as arm elements is removed, and the snubber capacitor sides of the diodes of both snubbers are connected to the diode circuit. By connecting the snubber capacitor through the handle, the charge of the snubber capacitor is discharged between the positive and negative stand arm elements through the handle.As a result, the di/dt of the self-extinguishing switching element is In addition to being able to reduce debt, not only is there no resistance in the snubber, but the current flowing through the diode circuit is converted to the DC power supply side via a current transformer, so compared to the conventional one. The power conversion efficiency can be greatly increased, and since both terminals of the secondary winding heel of the current transformer are connected to the DC power supply via a diode bridge circuit, overvoltage can be suppressed in the current transformer. This provides excellent effects such as eliminating the need to provide an element.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing an inverter constructed by connecting conventional self-extinguishing switching elements in a bridge manner, FIG. 2 is an operating waveform diagram of each part of the inverter shown in FIG. 1, and FIG. A circuit diagram showing an inverter device as an example,
Fig. 4 is an operating waveform diagram of each part of the inverter device shown in Fig. 1; Inverter device 1' in the figure (this is an operation waveform diagram of the introspection section. In the figure, IU, IX... gate turn") → Noirister (GTO), 2U, 2X... reactor, 3
U. 3X-...Za) Return diode, 4 U, 4 X
, Ei LJ, 5 X...Snubber, 6...Diode circuit, 7...Current transformation): I? , 7a. 7b...terminal, 8a to 8f, 42u,
42x, 52u, 52x... diode, 41
u, 41x, 51u, 51x... snubber capacitor, 43u, 43X... resistor, P...
・Positive 44, N...Negative pole, U...AC output terminal, X,
Y, Z... arms. In addition, in the figures, the same reference numerals indicate the same or equivalent parts. Agent Masuo Oiwa Figure 1 Figure 2 T. ↑Cao↑2 Figure 5 Figure 6 T1 Self

Claims (1)

[Claims] In an inverter in which a self-extinguishing switching element is used as an arm element, and a reactor is provided in each positive and negative arm element,
A snubber consisting of a snubber capacitor and a diode connected in series with the snubber is connected in parallel to each of the positive and negative arm elements, and the snubber capacitor side of the diode of each snubber is connected to a diode circuit in the forward direction with respect to each of the diodes. A plurality of arms are provided in which the secondary windings of the current transformers of each arm are connected in series, and the secondary windings of the current transformers of each arm are connected in series. An inverter device characterized in that a point is connected to an AC terminal of a diode bridge circuit bridge-connected to a DC power source.