DE102020108100B4 - Arrangement for increasing the performance of a power module - Google Patents

Abstract

Arrangement (1) for increasing the performance of power modules (2, 8, 9) by reducing the parasitic inductances in the arrangement (1), the arrangement (1) having a first power module (2), a first intermediate circuit capacitance (3) and a first external line (4) for the electrical connection between the power module (2) and the first intermediate circuit capacitor (3), with a second intermediate circuit capacitor (5) and a second external line (6) for the electrical connection between the second intermediate circuit capacitor (3) and are provided in the first power module (2), the second intermediate circuit capacitance (5) being connected electrically in parallel with the first intermediate circuit capacitance (3) and the first intermediate circuit capacitance (3) and the second intermediate circuit capacitance (3) being connected to the first power module (2) are electrically connected in series, characterized in that seen in a first direction of extension (100), the first intermediate circuit capacitor (3) above rhalb the first power module (2) and the second intermediate circuit capacitor (5) is arranged below the first power module (2).

Description

The invention relates to an arrangement for increasing the performance of power modules by reducing the parasitic inductances in the arrangement or the power modules, the arrangement comprising a first power module, a first intermediate circuit capacitance and an external line for the electrical connection between the first power module and the first intermediate circuit capacitance .

The power modules are known from the prior art and are installed by third parties in corresponding machine configurations. However, the power modules have undesired parasitic inductances which, in conjunction with the power supply, represent an overall inductance through an intermediate circuit capacitance, which is not compensated for in the prior art, but which significantly influences the switching properties.

JP 2005 - 65 412 A describes a device by means of which an overall inductance can be reduced. In this case, the device has a plurality of capacitors which are arranged in parallel with one another and which are connected in series with the inverter.

It is therefore the object of the present invention to specify an arrangement for increasing the performance of power modules, by means of which a reduction in the parasitic inductances in the power modules or the arrangement can be achieved.

This problem is solved by an arrangement with the features of patent claim 1.

The core idea of the invention is to provide an arrangement for increasing the performance of power modules by reducing the parasitic inductances in the arrangement, the arrangement having a first power module, a first intermediate circuit capacitance and a first external line for the electrical connection between the first power module and the first intermediate circuit capacitance includes, wherein the first intermediate circuit capacitor and the first power module are electrically connected in parallel.

The parasitic inductances in the power modules arise from the fact that an inductance is described by the internal lines of the power modules, which are at a distance from one another in every spatial direction and are connected to an electrical positive or negative pole, i.e. by the volume or the area which the internal lines enclose. However, these parasitic inductances are undesirable and impair the efficiency of the power module with regard to the switching speed, which is directly dependent on the commutation inductance.

However, since, as described, the power modules are already prefabricated by a third-party supplier, these line arrangements can no longer be changed within the respective power module, so that other options must be sought to further reduce the inductances of the entire system.

The inductance of the system or the arrangement is also dependent on the inductance of the intermediate circuit capacitance or the intermediate circuit capacitances.

According to the invention, it is proposed to electrically connect the first intermediate circuit capacitor and the first power module in series.

Viewed electrically, the first power module has an inductance and likewise the first intermediate circuit capacitance and the second intermediate circuit capacitance. By connecting the first intermediate circuit capacitance and the second intermediate circuit capacitance in parallel, the associated inductances are correspondingly connected in parallel, so that the inductance of the intermediate circuit capacitances can be reduced and the overall inductance of the arrangement can be reduced accordingly, since parallel connection of inductances leads to a reduction in the overall inductance .

In this case, it is particularly preferred that the inductance of the first and/or the second intermediate circuit capacitance can be made as small as possible, so that the effect of reducing the overall inductance of the arrangement can be expanded further. The respective power module can particularly preferably have a connection area which can be electrically connected to the first external line, for example screwed, soldered or the like. The connection area preferably includes a connection area for an electrical positive pole and for an electrical negative pole. The main area of application for these power modules is in the field of inverters for an electric motor, whereby a DC voltage is applied and converted into an AC voltage.

Depending on the design of the electric motor, it can be provided that a second power module, a third power module, ..., n power modules are specified to the corresponding phases of the electric motor to be able to cover.

According to the invention, a second intermediate circuit capacitance is provided, which is connected electrically in parallel with the first intermediate circuit capacitance and the first power module and is electrically connected to the first power module. A second external line is also provided for the electrical connection between the second intermediate circuit capacitance and the first power module.

The previously described effect of connecting inductances in parallel can be further increased by means of a further intermediate circuit capacitance, here the second intermediate circuit capacitance. In this case, it is provided that the second intermediate circuit capacitance is connected in parallel with the first intermediate circuit capacitance and in series with the first power module.

More preferably, it can be provided that the further power modules, if necessary, are also electrically connected to the first intermediate circuit capacitance, analogously to the configuration with regard to the first power module.

The same configuration can also be provided with regard to the second intermediate circuit capacitance, so that overall the first intermediate circuit capacitance is arranged in parallel with the second intermediate circuit capacitance and in series with each individual power module.

According to a further preferred embodiment, it is provided that n intermediate circuit capacitors are provided, which are arranged parallel to one another and in series with the first power module and optionally each additional power module and are electrically connected to the first power module and optionally the respective additional power module.

“In series” with regard to the intermediate circuit capacitance/intermediate circuit capacitances to the power module/power modules is understood to mean that the conglomerate of all intermediate circuit capacitances is connected in series to the power module/power modules.

The inductance of the arrangement can be further reduced by connecting n inductances of intermediate circuit capacitances in parallel.

The number n naturally depends on the particular design of the arrangement, with the arrangement depending on what its field of application actually is.

As already described above, the parasitic inductance of the power modules can no longer be changed afterwards, but the inductances of the intermediate circuit capacitances can still be changed in the configuration of the arrangement such that the inductance of the arrangement can still be changed.

According to a particularly preferred embodiment, it is therefore provided that each intermediate circuit capacitance comprises at least two partial capacitances, with the partial capacitances being arranged electrically in parallel with one another. By connecting the partial capacitances in parallel, the values of the capacitances add up to a certain value, the inductances of the partial capacitances decreasing overall as a result of the parallel connection, so that the inductance of the intermediate circuit capacitances can be reduced by a large number of partial capacitances. Seen overall, the capacitance of the intermediate circuit capacitance is formed by many small partial capacitances with low inductance with regard to the total intermediate circuit capacitance.

The inductance of the arrangement can therefore be further reduced overall by reducing the inductances of the intermediate circuit capacitances.

According to a further preferred embodiment, it is provided that a second power module is provided, the first external line being provided for the electrical connection between the second power module and the first intermediate circuit capacitance and the external second line for the electrical connection between the second power module and the second intermediate circuit capacitance and the second power module is electrically connected in parallel with the first power module and the first intermediate circuit capacitor and the second power module are electrically connected in series.

According to a further preferred embodiment, it is provided that a third power module is provided, the first external line being provided for the electrical connection between the third power module and the first intermediate circuit capacitance and the external second line for the electrical connection between the third power module and the second intermediate circuit capacitance and the third power module is arranged electrically in parallel with the first power module and the first intermediate circuit capacitor and the third power module are electrically connected in series.

More preferably, the second and the third power module are arranged parallel to one another, in the electrical sense.

The second power module and the third power module and possibly each additional power module are arranged in the same way with respect to the electrical arrangement in relation to the intermediate circuit capacitances and the power modules. This means that each power module is electrically connected to the first and second intermediate circuit capacitors, with the first and second intermediate circuit capacitors being arranged in series with one another electrically, and the respective power modules are also arranged electrically in parallel with one another.

The same explanations also apply with regard to each further intermediate circuit capacitance, that is to say a third intermediate circuit capacitance, a fourth intermediate circuit capacitance, . . . an mth intermediate circuit capacitance.

In order to further increase the efficiency of the respective power module, a preferred embodiment provides for a first heat sink for cooling the first power module to be arranged between the first intermediate circuit capacitor and the first power module, viewed in a first direction of extent of the arrangement.

This also applies to each additional power module, so that each power module is connected to the first heat sink for cooling the respective power module, with the first heat sink also being arranged between the first intermediate circuit capacitor and the respective corresponding power module.

According to a particularly preferred embodiment, each power module has at least one flat area which can be brought into thermal contact with the first heat sink, in particular mechanically connected to one another. The area of contact between the power modules and the first heat sink can be increased by the planar design of the power modules and possibly the planar design of the first heat sink in the area of the first region of the respective power module. This also increases the cooling capacity accordingly.

According to the invention, the first intermediate circuit capacitance is arranged above the first power module and the second intermediate circuit capacitance is arranged below the first power module, viewed in a first direction of extent. This makes it possible to provide a space-saving arrangement within the arrangement, so that the arrangement itself can be made more compact.

According to a further preferred embodiment, it is provided that, seen in a first direction of extent of the arrangement, a first heat sink for cooling the first power module is arranged between the first intermediate circuit capacitor and the first power module, and a second heat sink for cooling the first power module is arranged between the second intermediate circuit capacitor and the first power module first power module is arranged. The first power module particularly preferably has a second flat area which can be thermally connected to the second heat sink, in particular mechanically connected to one another. The second heat sink particularly preferably also has a flat portion in the area of the second area of the first power module. An analogous corresponding arrangement applies to possible further power modules. Two-sided cooling can therefore be implemented by means of two heat sinks, which are arranged in particular above and below the power module, as a result of which the cooling capacity can be increased again.

According to a further preferred embodiment, it is provided that the first heat sink and/or the second heat sink do not consist of a metal, but are preferably made of a plastic. If a heatsink were made of metal or other conductive materials, the compensation for the parasitic inductance could be negated again, since the conductive properties would again generate inductances.

Provision can particularly preferably be made for a fluid, which is preferably a liquid, for example water, oil or the like, or a gas, for example air, to flow through the first heat sink or the second heat sink.

Further advantageous embodiments emerge from the dependent claims.

• 1: Anordnung gemäß einer bevorzugten Ausführungsform;
• 2: Ersatzschaubild für einen Teil der Anordnung gemäß 1;
• 3: Ersatzschaubild für eine Zwischenkreiskapazität gemäß einer bevorzugten Ausführungsform;
• 4: Anbindung der Teilkapazitäten zueinander.

Further objects, advantages and advantages of the present invention can be seen from the following description in connection with the drawings. Here show:

• 1 : Arrangement according to a preferred embodiment;
• 2 : Substitute diagram for part of the arrangement according to 1 ;
• 3 : equivalent diagram for an intermediate circuit capacitance according to a preferred embodiment;
• 4 : Connection of the partial capacities to each other.

In the figures, the same components are to be understood with the corresponding reference numbers. For the sake of clarity, in some figures components may not be provided with a reference number, but they have been referred to elsewhere.

In the 1 an arrangement 1 according to a particularly preferred embodiment is shown. The arrangement 1 comprises a first power module 2, a second power module 8 and a third power module 9, with each power module 2, 8, 9 having a first connection 16 and a second connection 17, which are connected to a first associated connection 18 and a second associated terminal 19 of a first intermediate circuit capacitance 3 and a second intermediate circuit capacitance 5 are connected.

By means of the intermediate circuit capacitors 3, 5, a voltage can be provided to the respective power module 2, 8, 9 by means of the connections 16, 17, 18, 19 described, with an alternating voltage being output by means of the respective power module 2, 8, 9. The voltage provided by the intermediate circuit capacitors 3, 5 is a DC voltage.

The connections 16, 17 of the respective power module 2, 8, 9 are arranged in a connection area 15 of the respective power module 2, 8, 9.

The associated connections 18, 19 represent part of a first external line 4 and a second external line 6, the first external line 4 being connected to the first intermediate circuit capacitor 3 and the respective power modules 2, 8, 9, so that by means of the first external line 4, an electrical voltage can be provided by the first intermediate circuit capacitor 3 to the power modules 2, 8, 9. The same applies analogously to the second intermediate circuit capacitance 5 with regard to the second external line 6.

It can also be seen that the first intermediate circuit capacitance 3 and the second intermediate circuit capacitance 5 each have a plurality of partial capacitances 7, the partial capacitances 7 being arranged in parallel with one another. By connecting the partial capacitances 7 in parallel, the capacitances of the partial capacitances 7 can be added, with the inductances of the partial capacitances 7 being reduced overall.

A first heat sink 10 and a second heat sink 11 are also provided for cooling the power modules 2, 8, 9, the first heat sink and the second heat sink 11 preferably being of identical design in the present case.

Seen in a first direction of extent 100, which in the present case corresponds to the height of the arrangement 1, the first heat sink 10 is arranged between the first intermediate circuit capacitor 3 and the power modules 2, 8, 9. The first heat sink 10 is preferably cuboidal with an upper side 13 and an underside 14 which are flat. The surface 13 is connected to the first intermediate circuit capacitor 3 and the underside 14 of the first heat sink 10 to corresponding flat areas 12 of the power modules 2, 8, 9. The flat area 12 is preferably parallel to the underside 14 of the heat sink 10. As a result, good thermal contact can be provided by a mechanical connection.

The same explanations also apply in an analogous manner to the second heat sink 11, the second heat sink 11 being arranged in the extension direction 100 between the second intermediate circuit capacitor 5 and the line modules 2, 8, 9, the upper side 13 of the second heat sink 11 being connected to a lower Flat area 12 `of the power modules 2, 8, 9 is connected, that the second heat sink 11 is arranged below the power modules 2, 8, 9 seen in the direction of extension 100. The flat area 12, as described above, is in particular an upper flat area 12, so that the first heat sink 10 is arranged above the power modules 2, 8, 9.

By the arrangement 1 according to the 1 cooling is provided on two sides by means of two heat sinks 10, 11 of the power modules 2, 8, 9. Furthermore, the arrangement 1 is particularly compact, since the intermediate circuit capacitances 3, 5 are arranged above or below the power modules 2, 3, 8, as seen in the direction of extent 100.

The power modules 2, 8, 9 are particularly preferably of the same design and lie essentially in a common plane, which can be represented by the upper flat area 12 or the lower flat area 12'.

The first direction of extent 100 is preferably the height, and further directions of extent 101, 102 are provided, with the second direction of extent 101 preferably representing the longitudinal extent of the arrangement 1 and the third direction of extent 102 representing the width of the arrangement 1.

The 2 shows a circuit diagram according to a preferred embodiment of the arrangement 1, a first intermediate circuit capacitance 3 and a second intermediate circuit capacitance 5 being provided. The first intermediate circuit capacitance 3 and the second intermediate circuit capacitance 5 include an unspecified number of partial capacitances 7 , which also represent a partial inductance 20 and a partial resistance 21 . The first connection 16 and the second connection 17 are also shown schematically with the first associated connection 18 and the second associated connection 19 of the intermediate circuit capacitors 3, 5.

How from the 2 As can be seen, the intermediate circuit capacitances 3, 5 are connected in parallel with one another and in series with the corresponding power modules 2, 8, 9, represented by the connections 16, 17.

How from the 2 it can be seen that the respective partial capacitances 7 in the intermediate circuit capacitance 3, 5 are arranged in parallel with one another. Correspondingly, the associated resistors 21 and the inductances 20 are also arranged in parallel with one another.

In the 3 an alternative embodiment of the arrangement 1 is shown, the intermediate circuit capacitances 3, 5 of the 2 in the 3 are connected in series. As a result, the intermediate circuit capacitances 3, 5 have been combined to form a single intermediate circuit capacitance, with the partial capacitances 7 of the respective intermediate circuit capacitances 3, 5 being electrically parallel to one another. This means in particular that the partial capacitances 7 add up again and the inductances 20 add up again inversely.

Simply put, the intermediate circuit capacitance shown is the 3 equivalent to the two intermediate circuit capacitors 3, 5 in the 2 . These differ only in the arrangement to each other.

In the 4 an intermediate circuit capacitance 3, 5 or a section thereof is shown, with partial capacitances 7 and in an exploded view with the corresponding external line 4, 6.

Each of the partial capacitances 7 comprises a first contact 22 and a second contact 23. The external line 4, 6 is constructed in layers and has a first conductor layer 24, a second conductor layer 25 and an insulating layer 26, with the Insulating layer 26 is arranged between the first conductor layer 24 and the second conductor layer 25 .

In this case, the first conductor layer 24 has first contact points 27 and through-openings 29 , the second conductor layer 25 having second contact points 28 and also through-openings 29 .

The first contact point 27 is designed in such a way that it is in electrical contact with the second contact 23, with the first contact 22 protruding through a through-opening 29 in the first conductor layer 24, with the through-opening 29 being designed in such a way that no contact is made between the first Contact 22 and the first conductor layer 24 is made.

With regard to the second conductor layer 25, this is the opposite case, that is, the first contact part 22 is electrically connected to the second contact point 28, the second contact 23 protruding through the one through-opening 29. The through-opening 29 of the first conductor layer 24 and the second conductor layer 25 are of essentially the same design. This also applies to the configuration of the first contact point 27 and the second contact point 28.

In this case, the insulating layer 26 is designed and provided in such a way that an electrical connection between the first conductor layer 24 and the second conductor layer 25 is avoided.

This configuration of the external lines 4, 6 therefore defines a current flow direction, with the first contact 22 being connected to the plus or minus pole and the second contact being connected to the minus pole or the plus pole.

The insulating layer 26 has passage openings 30 through which the first contact 22 and the second contact 23 protrude. In this case, whether the first contact 22 and the second contact 23 touch the insulating layer 26 or not is irrelevant since the insulating layer 26 is formed in such a way that electrical insulation is provided. That is, the insulating layer 26 itself is non-conductive.

The various embodiments with all their features can be combined and exchanged as desired.

Reference List

1

arrangement

2

first power module

3

first intermediate circuit capacitance

4

first external line

5

second intermediate circuit capacitance

6

second external line

7

partial capacity

8th

second power module

9

third power module

10

first heatsink

11

second heatsink

12

flat area

13

top heatsink

14

Underside of the heat sink

15

connection area

16

first connection

17

second connection

18

first associated port

19

second associated port

20

partial inductance

21

partial resistance

22

first contact

23

second contact

24

first conductor layer

25

second conductor layer

26

insulating layer

27

first point of contact

28

second point of contact

29

passage opening

30

passage opening

100

first extension direction

101

second extension direction

102

third extension direction

Claims (8)

Arrangement (1) for increasing the performance of power modules (2, 8, 9) by reducing the parasitic inductances in the arrangement (1), the arrangement (1) having a first power module (2), a first intermediate circuit capacitance (3) and a first external line (4) for the electrical connection between the power module (2) and the first intermediate circuit capacitor (3), with a second intermediate circuit capacitor (5) and a second external line (6) for the electrical connection between the second intermediate circuit capacitor (3) and are provided in the first power module (2), the second intermediate circuit capacitance (5) being connected electrically in parallel with the first intermediate circuit capacitance (3) and the first intermediate circuit capacitance (3) and the second intermediate circuit capacitance (3) being connected to the first power module (2) are electrically connected in series, characterized in that viewed in a first direction of extent (100), the first intermediate circuit capacitance (3) ob above the first power module (2) and the second intermediate circuit capacitor (5) is arranged below the first power module (2). Arrangement (1) according to claim 1 , characterized in that n intermediate circuit capacitors (3, 5) are provided, which are arranged parallel to one another and in series with the first power module (2) and are electrically connected to the first power module (2). Arrangement (1) according to one of Claims 1 until 2 , characterized in that each intermediate circuit capacity (2, 5) comprises at least two partial capacities (7), wherein the partial capacities (7) are arranged electrically parallel to one another. Arrangement (1) according to one of Claims 1 until 3 , characterized in that a second power module (8) is provided, the first external line (4) for the electrical connection between the second power module (8) and the first intermediate circuit capacitor (3) and the second external line (6) for the electrical connection is provided between the second power module (8) and the second intermediate circuit capacitor (5) and the second power module (8) is arranged electrically in parallel with the first power module (2) and the first intermediate circuit capacitor (3) and the second power module (8) are electrically in are connected in series. Arrangement (1) according to one of Claims 1 until 4 , characterized in that a third power module (9) is provided, the first external line (4) for the electrical connection between the third power module (9) and the first intermediate circuit capacitor (3) and the second external line (6) for the electrical connection is provided between the third power module (9) and the second intermediate circuit capacitor (5) and the third power module (8) is arranged electrically in parallel with the first power module (2) and the first intermediate circuit capacitor (3) and the second power module (8) are electrically in are connected in series. Arrangement (1) according to one of Claims 1 until 5 , characterized in that viewed in a first extension direction (100) of the arrangement (1) between the first intermediate circuit capacitor (3) and the first power module (2) a first heat sink (10) for cooling the first power module (2) is arranged. Arrangement (1) according to one of Claims 1 until 6 , characterized in that seen in the first extension direction (100) of the arrangement (1) between the first intermediate circuit capacitor (3) and the first power module (2) a first heat sink (10) for cooling the first power module (2) is arranged and between a second heat sink (11) for cooling the first power module (2) is arranged between the second intermediate circuit capacitor (5) and the first power module (2). Arrangement (1) according to claim 6 or 7 , characterized in that the first heat sink (10) and / or the second heat sink (11) are not made of metal, are preferably made of a plastic.

Images