JP2007174760A - Power converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power converter which secures normal operation and also is small and inexpensive. <P>SOLUTION: This power converter 1 has a semiconductor module 21 which has a semiconductor element within, a cooler 22 which cools the semiconductor module 21, a control circuit 3 which controls the semiconductor module 21, being electrically connected with the signal terminal of the semiconductor module 21, a bus bar 41 which lets a current into semiconductor module 21, being electrically connected with the main electrode terminal 211 of the semiconductor module 21, a snubber capacitor 423 which is electrically connected with the main electrode terminal 212 via the bus bar 41, a smoothing capacitor 422, and a reactor 43. The snubber capacitor 423 is surrounded on at least three sides by the cooler 22, the smoothing capacitor 422, and the reactor 43. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power conversion device such as an inverter device using a semiconductor module.

  For example, in a hybrid vehicle having both an internal combustion engine and an electric motor as a drive source, and other vehicles having an electric motor as a drive source, a large-capacity inverter that performs bidirectional conversion between DC power and AC power is required. And Therefore, various power converters including this inverter have been developed.

  The inverter circuit (power conversion circuit) is configured using a semiconductor module incorporating an IGBT element or the like, but has a large capacity as described above, and therefore generates a large amount of heat. Therefore, the power converter is configured by incorporating a cooler that cools the semiconductor module.

In addition, the power conversion apparatus includes a power wiring unit that inputs and outputs current to and from the semiconductor module, and a control circuit unit that controls the semiconductor module.
And in order not to give the influence of the electromagnetic noise resulting from the large current which flows into a power wiring part to a control circuit part, as shown in FIG. 4, the main circuit part 92 is made into the power wiring part 94 and the control circuit part. The power converter device 9 arrange | positioned between 93 is disclosed (patent document 1). The power wiring unit 94 includes a bus bar 941, a capacitor 942 and a reactor 943 connected to the main circuit unit 92 by the bus bar 94.

  Examples of the capacitor 942 include a filter capacitor, a smoothing capacitor, and a snubber capacitor. Among them, the snubber capacitor suppresses a voltage surge generated during the switching operation of the semiconductor module, and prevents the semiconductor module from being damaged by an overvoltage. Therefore, an inrush current for absorbing a surge voltage flows in the snubber capacitor every time the semiconductor module is switched, and high-frequency electromagnetic noise is radiated from the snubber capacitor itself. The electromagnetic noise may cause malfunction of the control circuit unit 93, may cause noise in the power supply for the control circuit supplied to the control circuit unit 93 through the signal connector, or may give noise to the radio of the vehicle.

  Therefore, in order to prevent the influence of electromagnetic noise radiated from the snubber capacitor, it is necessary to provide electromagnetic shielding means made of an iron plate or the like around the snubber capacitor. However, providing such electromagnetic shielding means anew increases the number of parts, and there is a problem that the manufacturing cost may increase and the size of the apparatus may be increased.

JP 2005-073374 A

  The present invention has been made in view of such conventional problems, and is intended to provide a small and inexpensive power conversion device while ensuring normal operation.

The present invention includes a semiconductor module containing a semiconductor element, a cooler that cools the semiconductor module, a control circuit unit that is electrically connected to a signal terminal of the semiconductor module and controls the semiconductor module, and the semiconductor module A bus bar that is electrically connected to the main electrode terminal and allows current to flow into and out of the semiconductor module, and a snubber capacitor, a smoothing capacitor, and a reactor that are electrically connected to the main electrode terminal via the bus bar. Have
The snubber capacitor is located in at least three sides by the cooler, the smoothing capacitor, and the reactor (Claim 1).

Next, the effects of the present invention will be described.
The snubber capacitor is surrounded by at least three sides by the cooler, the smoothing capacitor, and the reactor. Therefore, electromagnetic noise radiated from the snubber capacitor can be shielded in at least three directions. Accordingly, by disposing components, wiring, equipment, and the like that are easily affected by electromagnetic noise in the above-described electromagnetic shielding direction, their normal operation can be ensured. As a result, the normal operation of the power conversion device can be ensured.

  In addition, as described above, by installing electromagnetic noise shielding with the cooler, the smoothing capacitor, and the reactor, it is possible to omit the installation of new electromagnetic shielding means. Therefore, it is not necessary to increase the number of parts for electromagnetic shielding, and the manufacturing cost can be reduced and the apparatus can be downsized.

  As described above, according to the present invention, it is possible to provide a small and inexpensive power conversion device while ensuring normal operation.

In the present invention (Claim 1), examples of the power converter include a DC-DC converter and an inverter. Moreover, the said power converter device can be used for the production | generation of the drive current which supplies with electricity to the alternating current motor which is motive power sources, such as an electric vehicle and a hybrid vehicle, for example.
Moreover, the said semiconductor module incorporates semiconductor elements, such as an IGBT element, for example, and comprises a part of power converter circuit.

Preferably, the power conversion device has a signal connector for supplying power to the control circuit unit, and the reactor is disposed between the signal connector and the snubber capacitor. ).
In this case, it is possible to prevent the electromagnetic noise radiated from the snubber capacitor from affecting the control circuit power supply supplied to the control circuit section through the signal connector. Thereby, normal operation in the control circuit unit can be ensured.

Moreover, it is preferable that the said bus bar is enclosed at least 3 sides by the said cooler, the said smoothing capacitor, and the said reactor (Claim 3).
In this case, electromagnetic noise radiated from the bus bar connected to the snubber capacitor can be shielded in at least three directions. This shields not only electromagnetic noise radiated from the snubber capacitor but also electromagnetic noise radiated from the bus bar connected to the snubber capacitor, and these electromagnetic noise affects the surrounding parts, wiring, equipment, etc. Can be prevented from giving.
Therefore, the normal operation of the power conversion device can be further ensured.

A power converter according to an embodiment of the present invention will be described with reference to FIGS.
As shown in FIGS. 1 and 2, the power conversion apparatus 1 of this example includes a semiconductor module 21 that contains a semiconductor element, and a cooler 22 that cools the semiconductor module 21. A control circuit unit 3 that controls the semiconductor module 21 is electrically connected to the signal terminal 211 of the semiconductor module 21. In addition, a bus bar 41 that allows current to flow into and out of the semiconductor module 21 is electrically connected to the main electrode terminal 211 of the semiconductor module 21. A snubber capacitor 423, a smoothing capacitor 422, a filter capacitor 421, and a reactor 43 are electrically connected to the main electrode terminal 211 via the bus bar 41. Although FIG. 1 shows an example in which the filter capacitor 421 and the smoothing capacitor 422 are provided separately, it is also possible to package them together.

As shown in FIG. 1, the snubber capacitor 423 is surrounded on three sides by the cooler 22, the smoothing capacitor 422, and the reactor 43.
In addition, the power conversion device 1 includes a signal connector 14 for supplying power to the control circuit unit 3, and a reactor 43 is disposed between the signal connector 14 and the snubber capacitor 423.
The bus bar 41 is also surrounded on three sides by the cooler 22, the smoothing capacitor 422, and the reactor 43.

  As shown in FIG. 3, the power conversion device 1 of this example is an inverter for an automobile that includes an inverter circuit 100 having a boost converter unit (DC-DC converter) 11 and an inverter unit 12. That is, the power conversion device 1 can be used to generate a drive current for energizing the AC motor 51 that is a power source of an electric vehicle, a hybrid vehicle, or the like.

  The boost converter unit 11 and the inverter unit 12 are provided with a plurality of semiconductor modules 21 each including an IGBT element 213 and a diode 214. The semiconductor module 21 performs a switching operation under the control of the control circuit unit 3 and controls a controlled current that enters and exits the main electrode terminal 212.

The boost converter unit 11 is provided with a reactor 43 for boosting the input voltage. Most of the constituent material of the reactor 43 is made of iron.
In addition, a filter capacitor 421 is connected to the external power supply 52 side of the boost converter unit 11. The filter capacitor 421 absorbs a ripple current included in the power supply current input from the DC external power supply 52 to the boost converter unit 11 and stabilizes the power supply current.

A smoothing capacitor 422 is connected between the boost converter unit 11 and the inverter unit 12. The smoothing capacitor 422 smoothes the output current of the boost converter unit 11 that becomes an intermittent current, and causes the inverter unit 12 to input a stable DC current.
The inverter unit 12 is provided with a snubber capacitor 423. The snubber capacitor 423 suppresses a voltage surge generated during the switching operation of the semiconductor module 21 to prevent the semiconductor module 21 from being damaged due to overvoltage.
Further, a three-phase AC motor 51 is connected to the inverter unit 12 via the bus bar 41, and the drive current generated by the inverter unit 12 is supplied to the AC motor 51.

  As shown in FIG. 1, the semiconductor module 21 is different from the module main body 210 containing a semiconductor element, the main electrode terminal 212 protruding from the module main body 210, and the protruding direction of the main electrode terminal 212 by about 180 degrees. The signal terminal 211 protrudes in the direction. And the module main-body part 210 has exposed the heat sink on the main surface (not shown).

  As shown in FIGS. 1 and 2, the cooler 22 has a plurality of cooling pipes 221 arranged so as to sandwich the module main body 210 from both sides. In this example, two semiconductor modules 21 are arranged side by side between adjacent cooling pipes 221. As a whole, the cooling pipes 221 and the rows of the semiconductor modules 21 are alternately stacked. As a result, all the semiconductor modules 21 are in a state in which both main surfaces are sandwiched between the cooling pipes 221.

Each cooling pipe 221 has a refrigerant flow path 222 therein, and is configured to allow a cooling medium to flow through it. Further, a connection pipe 223 provided with a bellows structure or a diaphragm structure is arranged so as to connect both ends of the plurality of cooling pipes 221, and two header portions 224 are formed. In addition, a refrigerant inlet 225 and a refrigerant outlet 226 connected to a cooling pipe 221 disposed at one end of the cooler 22 in the stacking direction are provided at the ends of the two header portions 224, respectively.
The cooler 22 is constituted by an aluminum extrusion-molded product or an aluminum plate press-molded body.

  And the module main-body part 210 can be cooled from both surfaces by distribute | circulating a cooling medium in the cooling pipe 221. FIG. Further, as shown in FIG. 1, each semiconductor module 21 is arranged such that the main electrode terminal 212 and the signal terminal 211 protrude in different directions substantially perpendicular to the longitudinal direction (horizontal direction) of the cooling pipe 221. Is done. That is, the main electrode terminal 212 protrudes downward and the signal terminal 211 protrudes upward.

  The control circuit unit 3 disposed above the cooler 22 is connected to the signal terminal 211, and the bus bar 41 disposed below the cooler 22 is connected to the main electrode terminal 212. A snubber capacitor 423, a filter capacitor 421, and a smoothing capacitor 422 arranged below the bus bar 41 are connected.

  The smoothing capacitor 422 can be constituted by a film capacitor formed by winding a metallized film in which a metal layer such as aluminum or zinc is deposited on the surface of a resin film, for example. The smoothing capacitor 422 is disposed below the snubber capacitor 423.

As shown in FIGS. 1 and 2, a reactor 43 is disposed in the space between the refrigerant inlet 225 and the refrigerant outlet 226 at the end of the cooler 22 in the stacking direction. . The arrangement position of the reactor 43 is also on the side of the snubber capacitor 423 and the bus bar 41.
As a result, the snubber capacitor 423 and the bus bar 41 are surrounded by the side reactor 43, the upper cooler 2, and the lower smoothing capacitor 422.
Further, the signal connector 14 is disposed on the upper side surface of the case 10 of the power conversion device 1. The reactor 43 is disposed between the signal connector 14 and the snubber capacitor 423 and the bus bar 41.

Next, the function and effect of this example will be described.
The snubber capacitor 423 is surrounded by at least three sides by the cooler 22, the smoothing capacitor 422, and the reactor 43. Therefore, electromagnetic noise radiated from the snubber capacitor 423 can be shielded in at least three directions. Thereby, for example, by arranging components, wiring, equipment, etc. that are easily affected by electromagnetic noise, such as the control circuit unit 3, the signal connector 14, the automobile radio, etc. in the above-described electromagnetic shielding direction, Operation can be ensured. As a result, the normal operation of the power conversion device 1 can be ensured.

  Further, as described above, the electromagnetic noise is shielded by the cooler 22, the smoothing capacitor 422, and the reactor 43, so that installation of a new electromagnetic shielding means can be omitted. Therefore, it is not necessary to increase the number of parts for electromagnetic shielding, and the manufacturing cost can be reduced and the apparatus can be downsized.

In addition, since the bus bar 41 is also surrounded by at least three sides by the cooler 22, the smoothing capacitor 422, and the reactor 43, electromagnetic noise radiated from the bus bar 41 connected to the snubber capacitor 423 is also at least three directions. Can be shielded. Thereby, in addition to the electromagnetic noise radiated from the snubber capacitor 423, electromagnetic noise radiated from the bus bar 41 connected to the snubber capacitor 423 is also shielded, and these electromagnetic noises are surrounded by surrounding parts, wiring, equipment, etc. Can be prevented.
Therefore, the normal operation of the power conversion device 1 can be further ensured.

  Further, since the reactor 43 is arranged between the signal connector 14 and the snubber capacitor 423 and the bus bar 41, electromagnetic noise radiated from the snubber capacitor 423 and the bus bar 41 is supplied to the control circuit unit 3 through the signal connector 14. The influence on the power supply for the control circuit can be prevented. Thereby, normal operation in the control circuit unit 3 can be ensured.

  As described above, according to this example, it is possible to ensure a normal operation and provide a small and inexpensive power conversion device.

The longitudinal cross-sectional explanatory drawing of the power converter device in an Example. FIG. 2 is a cross-sectional explanatory view taken along line AA in FIG. Explanatory drawing of the power converter circuit in an Example. The perspective explanatory drawing of the power converter device in a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Power converter 21 Semiconductor module 211 Signal terminal 212 Main electrode terminal 22 Cooler 3 Control circuit part 41 Bus bar 422 Smoothing capacitor 423 Snubber capacitor 43 Reactor

Claims (3)

A semiconductor module containing a semiconductor element, a cooler for cooling the semiconductor module, a control circuit unit that is electrically connected to a signal terminal of the semiconductor module and controls the semiconductor module, and a main electrode terminal of the semiconductor module A bus bar electrically connected to the semiconductor module, and a snubber capacitor, a smoothing capacitor, and a reactor electrically connected to the main electrode terminal through the bus bar,
The snubber capacitor is surrounded by at least three sides by the cooler, the smoothing capacitor, and the reactor.   2. The power converter according to claim 1, wherein the power converter has a signal connector for supplying power to the control circuit unit, and the reactor is disposed between the signal connector and the snubber capacitor. Power converter.   3. The power conversion device according to claim 1, wherein the bus bar is surrounded by at least three sides by the cooler, the smoothing capacitor, and the reactor.

Images