JPS59153476A - Inverter device - Google Patents

Abstract

PURPOSE:To alleviate wiring inductance by approaching or twisting power connecting wires and load connecting wires of an inverter unit which is divided for each phase unit at every unit and extending them to the vicinity of a DC power source. CONSTITUTION:An inverter device 2a is divided into a U-phase inverter unit 7 and a V-phase inverter unit 8. The power connecting wirings 15, 16, 17, 18 and load connecting wirings 19, 20 of the units 7, 8 are approached or twisted at every unit, extended to the vicinity of a DC power source 1a, and connected to the power source 1a or a load 3a.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an inverter device that reduces wiring inductance of connection wiring that connects between a DC power source and an inverter unit.

Generally, when a semiconductor element is used as the switching means of an inverter unit, the energy stored in the connection line is applied to the semiconductor element as a leaking voltage when the power supply is switched off. In order to suppress this voltage below the permissible value,
A snubber circuit consisting of capacitors, resistors, diodes, etc. is required. If the snubber circuit with the connecting wire has a large inductance (similar to the wiring inductance),
The circuit is also large and expensive.

In order to reduce this wiring inductance, a configuration as shown in FIG. 1 has been known.

FIG. 1 is a schematic diagram of a conventional single-phase bridge inverter device. FIG. 1(A) shows the connection wires arranged close to each other, and FIG. 1(B) shows the connection wires twisted together.

In Figures 1 (A) and (B), 1 is a DC power supply, 2 is an impark device in which the entire pre-pull circuit is configured as one unit, 3 is a load, and 6 is a terminal connected to the P pole of the DC power supply 1. The power supply connection line consists of a P-side power supply connection line 4 and an N-side power supply connection line 5 for connecting to the ON pole of the DC power supply 1.

DC power supplied from a DC power source 1 via a wiring cable 6 is converted into AC power by an inverter 2 and supplied to a load 3. The inverter 2 uses transistors as switching means.

In this device, since the inverter device is configured as a square unit, the wiring inductance that becomes a problem here is the power supply connecting wire 6 between the DC power source 1 and the inverter 2.
Although the inductance is , current flows in each pole connection wire 4.5 of the power supply connection line 6 between the DC power supply 1 and the inverter 2 in opposite directions as shown by the arrows.

Therefore, by arranging the connecting wires 4 and 5 close to each other as shown in (A) or twisting them together as shown in (B), the wiring inductances are canceled out. Therefore, wiring inductance is reduced. In addition, wiring inductance can also be reduced by shortening the power supply connection line 6 between the DC power supply 1 and the inverter 2.

These methods are effective when the inverter device 2 is small and the influence of wiring inductance within the device is so small that it is not necessary to consider it.

FIG. 2 is a schematic configuration diagram of a conventional large-capacity inverter device. In Fig. 2, 13 is a DC power supply, 3a is a load, and 6
A is a P-side power connection line 4a, an N-side power connection line 5a, and the power connection line 2a is constructed by combining a U-phase inverter unit 7 and a V-phase inverter unit 8, which are divided into each phase. Inverter device, 9.10 is a connection line between inverter units 7.8, 11, 12, 13,
14 is a transistor.

As shown in Figure 2, when the inverter device becomes larger,
It becomes necessary to configure the inverter device 2a by dividing it into one phase unit, such as a U-phase inverter unit 7 and a V-phase inverter unit 8.

In such a large-capacity device, each phase is unitized, so the connecting wires 9 and 10 between the units in the device become long, and the wiring inductance of the connecting wires 9 and 10 between the units cannot be ignored. It gets bigger.

Transistor +, i, 14 is in 0 on” state, l-
When the transistors 12 and 13 are in the "off" state, a current t flows from the DC power source A to the transistor 11 of the U-phase inverter unit 7 via the P-side connection line 4a. The current flowing into the transistor 11 flows through the load 3a to the transistor 14 of the V-phase inverter 7.
It's crowded. The current flowing into the transistor 14 is a connection line]
,0. It returns to the DC power supply 1a via the N-side connection line 5a. At this time, the two connection lines 4a of the power supply connection line 6a.

Since current flows in opposite directions to 5a, the P side connecting wire 4
By arranging a and the N-side connection wire 5a close to each other, the wiring inductance can be reduced by canceling each other out. Therefore, there is no way to reduce the wiring inductance, resulting in a large inductance.

Deaf, transistors 12 and 13 are "on" and transistor 11. , 14 are in the 6'' off state, the current flows from the DC power supply 1a to the V side via the P side connection wire 4a and the connection wire 9.
It flows into the transistor 13 of the phase inverter unit 8. The current flowing into the transistor 13 flows into the transistor 12 of the U-phase impark unit 7 via the load 3a. The current flowing into the transistor 12 returns to the DC power supply 1a via the N-side connection line 5a. At this time,
Since current flows in the two connection lines 4a and 5a of the power supply connection line 6a in opposite directions, the wiring inductance can be reduced by arranging both the connection lines 4a and 5a close to each other. However, the wiring inductance of the inter-unit connection line 9 cannot be reduced.

As described above, in an inverter device in which a conventional inverter circuit is divided into one and a half phases, the inter-unit connection line 9. ] Since it is not possible to reduce the wiring inductance of 0, the snubber circuit can reduce the large wiring inductance, but this increases the structural constraints of the inverter unit, resulting in poor productivity and poor maintainability. There are drawbacks.

In contrast, the present invention eliminates the above-mentioned drawbacks, reduces wiring inductance even when applied to large-capacity devices, and reduces wiring inductance when the power supply or switching element is switched on.
Suppressing voltage generated by wiring inductance/
The purpose of this invention is to provide an inexpensive and compact inverter device by downsizing the snubber circuit. According to the present invention, this purpose is to construct an inverter unit divided into one phase unit in the impark unit.
This is achieved by connecting the RI, silicon connection wire, and load connection wire to each unit in a nearby trench or twisting them together, extending them to the vicinity of the DC power source, and connecting them to the DC power source or load.

Hereinafter, the present invention will be explained in detail based on examples.

FIG. 3 shows the circuit configuration of the single-phase bridge inverter device of the present invention. FIG. 3(A) shows the wiring cables arranged close together, and FIG. 3(B) shows the wiring cables twisted together. In FIG. 3, 13 is a DC power supply, 2a is an inverter device divided into a U-phase impark unit 7 and a ■-phase impark unit 8, and 3a
is the load, 11, i,2.

13 and 14 are transistors, 15 is a load connection line for connecting the U-phase P side power supply, and 15 is a load connection line for the V-phase. In FIG. 3, a U-phase inverter unit 7 and a V-phase inverter unit 8 are individually connected to output terminals P and N of the DC power supply 1a. I of U-phase inverter unit 7
A load 3a is connected between the J-phase negative load connection line 19 and the V-phase load connection line of the ■-phase inverter unit 8. The connection between the DC power supply 1a and the U-phase inverter unit 7 uses three connection wires: a U-phase P-side power connection line 15, a U-phase load connection line 19, and a U-phase N-side power connection line 160. These connecting wires are arranged closely in parallel in FIG. 3(A), and twisted together in FIG. 3(B). The U-phase load connection line 19 is quadrupled by these power supply connection lines so as to be electromagnetically closely coupled to both power supply connection lines], 5, and 16, and its connection terminal to the load 3a is connected to the DC power supply 1a. It is drawn from the immediate vicinity of .

Further, the V-phase inverter unit 8 also has a wiring configuration similar to that of the U-phase inverter unit 7.

In such a configuration, transistors 11 and 14 are in one ON state and transistors 12 and 13 are in one state.
In this state, the current flows from the DC power supply 1a as shown by the solid arrow.
from the U-phase P side power supply connection line 15 to the transistor 11 of the U-phase inverter unit 7.

The current flowing into the core transistor 11 flows into the load 3a via the U-phase load connection line 19. From the load 3a to the ■ phase inverter unit 8 via the V phase load connection line 21)
flows into the L transistor 14. The transistor 14
The current flowing into the V-phase N-side power connection line 18 returns to the DC ttt source 1a. At this time, the currents flowing through the U-phase P-side power supply connection line 15 and the U-phase load connection line 19, as well as the (2) phase N-side power supply connection line 18 and (2) phase load connection line, have the same current value and are in opposite directions. Become.

At this time, since the power supply connection line and the load connection line of each phase impact unit are arranged close to each other, the wiring inductance of these connection lines cancels each other out and is reduced.

Similarly, when the transistors 12 and 13 are in the "on" state and the transistors 11 and 14 are in the "off" state, the current flows from the DC power supply 1a to the It flows into the transistor 13 of the inverter unit 8. The current flowing into the transistor 13 flows into the load 3a via the V-phase load connection line. It flows from the load 3a to the transistor 12 of the U-phase inverter unit 7 via the U-phase load connection line 19. The current flowing into the transistor] 2 is returned to the DC power supply 1a via the U-phase N-side power supply connection line 16. At this time as well, the currents flowing through the phase P-side power supply connection line 17 and the V-phase load connection line 20, and the U-phase N-side power supply connection line 16 and the U-phase load connection line 9 have equal current values and are opposite to each other. direction. Even at this time, the wiring inductance between the power supply connection line and the load connection line of each phase inverter unit is reduced by canceling each other out.

If the power supply connection wire and load connection wire of each unit are twisted together as shown in Figure 3 (B), the electromagnetic coupling between each connection wire will become even tighter and stronger, so The effect of reducing inductance is further increased, and wiring inductance can be made extremely small.

FIG. 4 shows a circuit configuration when the present invention is implemented in a three-phase bridge inverter device.

Figure 4 (A) shows the connection lines arranged close together;
Figure (B) shows the connection wires twisted together.

In Fig. 4, 1a is a DC power supply, 2a is a three-phase inverter device divided into a U-phase inverter unit 7, a V-phase inverter unit 8, and a W-phase inverter unit 24, 3ah is a load, and 21 is a W-phase P side. Power connection line, 72
The W-phase load connection line is the W-phase N-side power connection line, and the other parts are the same as in the case of FIG.

Such a three-phase inverter operates in the same way as the single-phase inverter shown in Figure 3, and the current flowing through the two power supply connection wires and load connection wires drawn out in close proximity to each other in each phase inverter unit. are in opposite directions and cancel out the wiring inductance, so the wiring inductance is significantly reduced.

In this way, the present invention configures an inverter device by dividing it into units of one phase of the bridge circuit, and for each unit, two power supply connection lines are drawn out from each unit for connecting the DC power supply, and one for connecting the load. A total of three load connection wires are placed close to each other or twisted together and extended at the nearest point of the DC power supply,
By adopting a configuration that connects to the power supply and load, it is possible to not only reduce the wiring inductance of the connection line between the DC power supply and the impark device, but also reduce the wiring inductance of the connection line between the inverter units, which was not possible with conventional methods. Wiring inductance can also be reduced. As a result, the snubber circuit can be miniaturized, resulting in the advantage of providing a compact and low-cost inverter device. In addition, in large-capacity devices, it is possible to divide the circuit into phase-based units, so it is possible to configure single-phase inverters and impark devices without being constrained by type restrictions. It also has the effect of improving productivity and maintainability.

[Brief explanation of the drawing]

Figure 1 (-J) is a circuit diagram of a conventional single-phase bridge impark device; Figure 2 is a circuit diagram of a conventional large-capacity inverter; and Figure 3 is a circuit diagram of a single-phase bridge inverter according to an embodiment of the present invention. Figure 4 shows a circuit diagram of a three-phase bridge inverter device according to an embodiment of the present invention. ■, 1a... DC power supply, 2, 2a... Inverter device, 3, 3a , 3b-load, 4.4a , 15,
17.21=・P side power supply connection line, 5, 5a, 16,
18, 23 = -N side power supply connection line, 7... U phase inverter unit, 8... V phase inverter unit, 1.1
, 12 , 13 , i4...transistor, 19
,20°22...Load connection line. I A゛ Rito 4F Rito Yamaguchi Ge (wa page mostly b1 year old 3 years old
(2) Age 4

Claims (1)

[Scope of Claims] 1) In an inverter device configured by combining a plurality of inverter units divided into one-phase circuit units of an inverter bridge circuit, two inverter units drawn out from each inverter unit for connection to a DC power source One load connection line drawn out to connect to the power supply connection line and the load is brought close to each other for each inverter unit and extended to the vicinity of the DC power supply t2, and connected to the DC power supply and the load, respectively. An inverter device characterized by: 2. The inverter device according to claim 1, wherein the power supply connection wires and load connection wires of each of the inverter units are twisted together and placed close to each other.