WO2008031370A1

WO2008031370A1 - Power semiconductor module for energy distribution, comprising an explosion protection system

Info

Publication number: WO2008031370A1
Application number: PCT/DE2006/001638
Authority: WO
Inventors: Markus Billmann; Jörg DORN; Werner Hartmann
Original assignee: Siemens Aktiengesellschaft; Fraunhofer Gesellschaft Zur Förderung Der Angewandten Forschung E. V.
Priority date: 2006-09-14
Filing date: 2006-09-14
Publication date: 2008-03-20
Also published as: DE112006004135A5

Abstract

The aim of the invention is to provide a power semiconductor module (2) comprising at least one power semiconductor (7) and connection terminals (9, 10) for connecting the power semiconductor module (2), ensuring extensive protection against explosion even in the event of an electric arc. To this end, a housing is filled with a filler (12) having a fixed temperature, each power semiconductor (7) and each connection terminal (9, 10) being arranged in the housing (11) and the filler (12) being used to attenuate an explosion caused by the formation of an electric arc.

Description

POWER SEMICONDUCTOR MODULE FOR ENERGY DISTRIBUTION WITH EXPLOSION PROTECTION

The invention relates to a power semiconductor module having at least one power semiconductor and terminals for connecting the power semiconductor module.

The invention further relates to a power converter valve branch of a series circuit of such power semiconductor modules and a power converter from such power converter valve branches.

A power semiconductor module of the aforementioned type is already known from DE 303 21 33. There, a pressure-contacted power semiconductor is described, which is jammed between two electrodes. The power semiconductor has a hollow-cylindrical ceramic component filled with silicon rubber as an explosion-proof element. In the event of an error, an overcurrent in the power semiconductor can lead to its destruction. First, the semiconductor material, such as silicon, locally becomes so hot that it vaporizes. This in turn leads to a pressure increase in the ceramic housing with possibly locally hot spots in the interior of the ceramic. In the case of extreme loads, this can lead to a bursting of the ceramic housing. The hollow cylindrical housing and the silicone rubber therefore serve to absorb the forces occurring in the explosion of the semiconductor. The prior art power semiconductor module, however, has the disadvantage that the hollow-cylindrical component with the introduced filler is an integral part of the power semiconductor itself and therefore has to be manufactured together with the power semiconductor. In addition, there is no effective protection against arcing occurring in the event of a fault. This is only at costly pressure-contacted power semiconductors acceptable.

DE 198 39 422 A1 likewise discloses a power semiconductor which is pressure-contacted between two electrodes. An integral part of the power semiconductor is a protective cover that surrounds the power semiconductor but not its electrodes. Due to the pressure contact of the power semiconductor no effective protection in Lichtbogenbild- fertilg is provided.

The object of the invention is therefore to provide a power semiconductor module of the type mentioned, in which a far-reaching explosion protection is ensured even when an arc occurs.

The invention solves this problem by a housing which is filled with a temperature-resistant filler, wherein each power semiconductor and each AnSchlussklemme are arranged in the housing and the filler for damping a through

Arcing caused by the explosion is established.

According to the invention, a housing is provided in which all components of the power semiconductor electronics are arranged. In the context of the invention, the housing can be produced independently of the power semiconductor or semiconductors. The power semiconductor electronics include, for example, the power semiconductors, their opposing freewheeling diodes and the control electronics for igniting the power semiconductors. The housing has sufficient strength to effectively absorb the explosion forces that occur in the event of a fault. The housing is supported by the temperature- and / or heat-resistant filling of the housing in the form of the temperature-resistant filler. The filler supports the housing in its protective effect even when an arc occurs, so that even when using bonded power semiconductors, an effective explosion protection is provided. All components are arranged inside the housing. This also applies to the electrodes of the power semiconductors, whose free ends are led out of the housing for connection purposes. Furthermore, connections for an energy store such as a capacitor are led to the outside. The power semiconductor module according to the invention is provided in particular for use in the field of energy transmission and power distribution. Of course, other application areas deviating therefrom, such as use as part of a power converter for motor control or the like, come into consideration as well.

Conveniently, the temperature-resistant filler is a plastically-elastically deformable polymer. Due to the plastic elastic properties of the elastomer, the explosive forces can be safely absorbed.

Advantageously, the housing is filled with the temperature-resistant filler. The components are initially placed in the housing during manufacture. Subsequently, the interior of the housing is filled with foam. When foaming, we introduced the filler as a foam in the housing and then cured. In this way it is ensured that the temperature-resistant filler is everywhere between the inner wall of the housing and the remaining components of the power semiconductor module. Only terminals are led out with their free ends from the housing and from the filler. Deviating from this, foam moldings are introduced into the housing in another embodiment. One such power semiconductor module is removable and thus possibly repairable.

Conveniently, the temperature-resistant filler is a fine-pored foam. It has been found that a temperature-resistant, fine-pored foam such as polyurethane has outstanding plastic-elastic properties, so that a sufficient explosion protection is given. Here, the fine closed pores of the foam supported the plastic-elastic properties.

Notwithstanding this, the temperature-resistant filler is an open-pore foam. Open-pored foams exhibit in the

Compared to closed-pore foams a larger area. Hot gases that penetrate the foam are therefore cooled better. ^'

According to a preferred embodiment of the invention, the one or more power semiconductors are at least partially so-called bonded power semiconductors. Bonded power semiconductors are inexpensive compared to pressure-contacted power semiconductors. As a rule, they consist of a multiplicity of semiconductor chips connected in parallel to one another and connected to one another via wires. In the event of a fault, however, the high currents cause the connections to break up or melt, with simultaneous arcing. However, the effects of the arc are reliably absorbed by the heat-resistant filler and the housing, so that damage to components arranged outside the housing of the power semiconductor module is largely avoided. Advantageously, the one or more power semiconductors are at least partially turn-off power semiconductors. From ^¬ switchable power semiconductors can be actively transferred, so by control pulses, both from a blocking position to a through position and from a passage position to a blocking position, so that the possibilities of control for the power semiconductor module are significantly increased. Switchable power semiconductors are, for example, IGBTs, IGCTs, GTOs or the like.

Advantageously, each power semiconductor which can be switched off is connected in parallel with an opposite freewheeling diode.

In the most preferred variant, the power semiconductor module comprises a first connection terminal, a second connection terminal, an energy store arranged outside the housing and a power semiconductor branch connected in parallel to the energy store, wherein the power semiconductor branch has two power semiconductors connected in series and each Power semiconductor an opposite freewheeling diode is connected in parallel, wherein the connection point of the emitter of a first power semiconductor of the power semiconductor branch and the anode of the first power semiconductor associated opposing freewheeling diode form the first terminal and the connection point of the power semiconductor of the power semiconductor branch or freewheeling diodes, the second terminal. In other words, the power semiconductor module comprises a so-called Marquardt circuit, which is already known from other publications. Such power semiconductor modules are for

Formation of a converter valve branch suitable, which consists of a series circuit of power semiconductor modules. The power converter valve branch is then part of a Stromrich- ters, which has a bridge circuit of converter valve branches.

Deviating from this, the power semiconductor module has a first connection terminal, a second connection terminal, an energy store and a power semiconductor branch having two series-connected power semiconductors connected in parallel to the energy store, wherein each power semiconductor is connected in parallel with an opposite freewheeling diode and the connection point of the collector of a first power semiconductor Power semiconductor branch and the cathode of the first power semiconductor associated opposing freewheeling diode, the first terminal and the connection point of the power semiconductor of the power semiconductor branch and the freewheeling diode form the second Anschlußklem- me. This is an alternative embodiment of the Marquardt circuit which has substantially the same characteristics. The energy store is expediently arranged outside the housing.

The housing is advantageously made of metal or plastic, in particular reinforced with fibers and / or fillers plastics. In principle, however, any suitable material can be used to manufacture the housing. What is essential here is that the housing has the necessary strength to be able to withstand the explosion forces in the event of a fault as far as possible without damage.

Advantageously, pressure relief openings for the targeted discharge of hot gases and / or particles are provided. Usefully, the pressure relief openings are in the. Housing provided at locations which are remote from adjacent components. According to a particularly preferred development of the invention, the energy of the filler which can be absorbed by plastically elastic deformation corresponds to the expected maximum arc energy. The maximum arc energy results, for example, from that in an energy store such as a

Capacitor stored energy. The deformation energy of the filler, that is to say the energy which can be absorbed by plastically elastic deformation, can be determined by experimental experiments. The deformation energy in turn depends on the material properties.

Further expedient embodiments and advantages of the invention are the subject of the following description of exemplary embodiments of the invention with reference to the figure of the drawing, wherein the

FIG. 1 shows an embodiment of power converter branches according to the invention,

FIG. 2 shows a replacement image representation of an exemplary embodiment of the power semiconductor module according to the invention,

FIG. 3 shows a replacement image representation of a further exemplary embodiment of the power semiconductor module according to the invention and FIG

Figure 4 shows an embodiment of the invention

Show power semiconductor module.

FIG. 1 shows an exemplary embodiment of converter branches 1 according to the invention, each consisting of a series connection of power semiconductor modules 2. The power converter valve branches 1 are arranged in series with each other. The number of power semiconductor modules 2 within a power converter valve branch 1 depends on the particular application, in particular according to the required voltages. The number may therefore vary between a few tens to several hundred power semiconductor modules 2.

Between the power converter valve branches 1, an AC voltage connection 3 is provided, which is provided for connection to a phase of an AC voltage network. At the end remote from the AC terminal 3 end of each

Power converter valve branch 1, a DC voltage connection 4 is provided. Thus, each power converter valve branch 1 is arranged between an AC voltage terminal 3 and a DC voltage terminal 4. An exemplary embodiment of a power converter according to the invention would therefore be, for example, six power converter valve branches connected in a bridge circuit, which is known as such, in the case of a three-phase alternating current network to be connected. This may be a so-called six-pulse bridge circuit but also a twelve-pulse bridge circuit.

2 shows an equivalent circuit diagram of an embodiment of a power semiconductor module according 2. It can be seen that each power semiconductor module 2 has an energy ^'giespeicher in the form of a capacitor. 5 The capacitor 5 is connected in parallel to a power semiconductor branch 6, wherein the power semiconductor branch 6 consists of a series circuit of two so-called IGBTs 7. Each IGBT 7 is a freewheeling diode 8 connected in opposite directions in parallel. The consisting of the controllable power semiconductors 7 and the opposing diodes 8 component together with the control electronics is hereinafter referred to as power electronics. The power electronics are connected to the capacitor 5 switched in parallel. FIG. 2 also shows a first connection terminal 9 and a second connection terminal 10, the first connection terminal 9 being connected to the emitter of the controllable power semiconductor 7 and simultaneously to the anode of the opposing diode 8 assigned to it, in other words to its connection point. connected is. The second connection terminal 10 is connected to the connection point of the controllable power semiconductors 7 and to the connection point of the opposing diodes 8. If the controllable power semiconductor 7 arranged between the connection terminals 9 and 10 is in its passage position, the voltage zero drops at the connection terminals 9 and 10. If, however, the said power semiconductor is in its blocking position, the controllable power semiconductor 7 not arranged between the connection terminals 9 and 10, however, in its through position, the voltage applied to the capacitor 5 drops between the connection terminals 9 and 10.

FIG. 3 shows an alternative embodiment of the power semiconductor module 2 according to FIG. 2. In contrast to the variant of a Marquardt circuit shown in FIG. 2, the first terminal 9 in FIG. 3 is connected to the collector of the turn-off power semiconductor 7 and to the cathode opposite freewheeling diode 8 connected. The second terminal 10 is connected to the connection point of the turn-off power semiconductor 7 and the freewheeling diodes 8. The exemplary embodiments of the Marquardt circuit shown in the figures are equivalent to one another and therefore have the same properties.

FIG. 4 shows an exemplary embodiment of the power semiconductor module 2 according to the invention in a schematic representation. The power semiconductor module 2 has a power semiconductor circuit according to FIG. 2 or FIG. 3. In FIG 4, however, only two power semiconductors 7 can be seen. In this case, each power semiconductor 7 is a bonded IGBT, thus having its own power semiconductor housing, in which a plurality of semiconductor chips are connected to each other in parallel with each other conductor connections. In the power semiconductor housing, the opposing freewheeling diodes are also arranged. The power semiconductor module 2 further comprises the said first connection terminal 9 and the said second connection terminal 10, which are designed for the supply and discharge of currents which are driven by a voltage, in particular high voltage.

The terminals 9 and 10 and the IGBT 7 are arranged in a housing 11 made of plastic with high mechanical strength. In addition, the space between the inner wall of the housing 11 is filled with a temperature-resistant filler 12. The temperature-resistant filler 12 is in the illustrated embodiment of a fine-pored open-cell foam whose flow resistance is large enough to retain the hot gas produced during arcing until its cooling to a few hundred degrees Celsius, so that adjacent structures or modules in their function not be affected. In particular, the temperature-resistant foam is able to completely absorb the energy released during the arcing by means of plastic-elastic deformation. The explosive escape of hot gases or particles from the housing 11 is avoided in this way.

Claims

claims

1. power semiconductor module (2) with at least one power semiconductor (7), and connection terminals (9,10) for connecting the power semiconductor module (2), characterized by a housing (11) which is filled with a temperature-resistant filler (12), wherein each power semiconductor (7) and each terminal (9, 10) are disposed in the housing (11) and the filler (12) is arranged to damp an arc-induced explosion.

2. Power semiconductor module (2) according to claim 1, characterized in that the temperature-resistant filler (12) is a plastically-elastically deformable polymer.

3. The power semiconductor module (2) according to claim 1 or 2, characterized in that the housing (11) is filled with the heat-resistant filler (12).

4. Power semiconductor module (2) according to one of the preceding claims, characterized in that the temperature-resistant filler (12) is a fine-pored foam.

5. power semiconductor module (2) according to one of the preceding claims, characterized in that the temperature-resistant filler (12) is an open-cell foam.

6. Power semiconductor module (2) according to one of the preceding claims, characterized in that the one or more power semiconductors are at least partially so-called bonded power semiconductors (7).

7. Power semiconductor module (2) according to claim 6, characterized in that the one or more power semiconductors (7) are at least partially disconnectable power semiconductors.

8. The power semiconductor module (2) according to claim 7, characterized in that each turn-off power semiconductor (7) an opposite freewheeling diode is connected in parallel.

9. power semiconductor module (2) according to any one of the preceding claims, e e e c e e n e d d e r c h a first terminal (9), a second terminal

(10), an outside of the housing (11) arranged energy storage (5) and a two series power semiconductors (7) having power semiconductor branch (6) in parallel to the energy storage (5), each power semiconductors (7) an opposite freewheeling diode (8) is connected in parallel and the connection point of the emitter of a first power semiconductor (9) of the power semiconductor branch (6) and the anode of the first power semiconductor (7) associated opposing freewheeling diode (8) the first terminal terminal (9) and the connection point of Power semiconductor (7) of the power semiconductor branch (6) and the freewheeling diodes (8) form the second terminal (10) ^¬ .

10. power semiconductor module (2) according to one of claims 1 to 8, characterized by a first terminal (9), a second terminal (10), an energy store (5) and a two-connected power semiconductors (7) having power semiconductor branch (6) in Parallel connection to the energy store (5), wherein each power semiconductor (7) an opposite freewheeling diode (8) is connected in parallel and the connection point of the collector of a first power semiconductor (7) of the power semiconductor branch (6) and the cathode of the first power semiconductor (7) associated opposite freewheeling diode (8) the first terminal (9) and the connection point of the power semiconductors (7) of the power semiconductor branch (6) and the freewheeling diode (8) form the second terminal (10).

11. Power semiconductor module (2) according to one of the preceding claims, characterized in that the housing (11) consists of metal or a plastic material.

12. Power semiconductor module (2) according to one of the preceding claims, e e c e n e c e n e d d e r c h

Pressure relief openings for the targeted discharge of hot gases and / or particles.

13. power semiconductor module (2) according to one of the preceding claims, characterized in that the absorbable by plastically elastic deformation energy of the filler (12) corresponds to the expected maximum arc energy.

14. Power converter valve branch (1), one of a series circuit of power semiconductor modules (2) according to one of the preceding claims.

15. Converter, g e c e n e c e s t d u r c h a bridge circuit of converter valve branches (1) according to claim 12.