DE102016204150A1 - Method, semiconductor module, power converter and vehicle - Google Patents

Abstract

The invention relates to two methods for producing a semiconductor module (1). Furthermore, the invention relates to two such semiconductor modules (1), in particular for a power converter (8) of a drive train of a vehicle (9). Furthermore, the invention relates to a power converter (8), in particular for a drive train of a vehicle (9), comprising at least one such semiconductor module (1). Finally, the invention relates to a vehicle (9), in particular hybrid or electric vehicle, comprising a drive train comprising such a power converter (8). In order to make the production of such a semiconductor module (1) simpler and more cost-effective or to provide or use a semiconductor module (1) that can be produced in a simple manner, the following method steps are proposed, among others: Provision of at least one semiconductor chip (2) comprising at least one electrical semiconductor chip - Providing at least one leadframe (4) having at least one electrical leadframe contact point (5), - Producing a respective contact connection (6) as a bond connection by means of bonding, wherein the respective contact connection (6) one of the electrical Semiconductor chip contact points (3) electrically connected to one of the electrical leadframe contact points (5). Furthermore, among other things, a corresponding semiconductor module (1), a corresponding power converter (8) and a corresponding vehicle (9) are proposed.

Description

The invention relates to two methods for producing a semiconductor module. Furthermore, the invention relates to two such semiconductor modules, in particular for a power converter of a drive train of a vehicle.

Furthermore, the invention relates to a power converter, in particular for a drive train of a vehicle, comprising at least one such semiconductor module. Finally, the invention relates to a vehicle, in particular hybrid or electric vehicle, comprising a drive train comprising such a power converter.

Semiconductor modules are used in a variety of applications, including soft-starters or converters, especially within a drive train of a hybrid or electric car, used.

The semiconductor chips installed in semiconductor modules or power modules must be contacted both on the top side and on the bottom side. These joints are exposed to high temperatures or temperature strokes and therefore limit the life of the module. For the chip-underside connection, soldering or sintering methods are used. Semiconductor modules usually also have a substrate whose electrical contacting is also a challenge.

For the chip topside connection so far solutions are known with wire bonds. These bonding wires consist among other things of pure or doped aluminum. Other solutions include brazing or sintering metal straps, metallized foils or leadframes onto the chips. Another solution is SiPLIT, a planar connection technology from Siemens AG.

Out DE 199 27 747 C1 For example, a multichip module for LOC (Leads-On-Chip) mounting is known in which a plurality of semiconductor chips arranged on a wafer wafer prior to LOC mounting are juxtaposed in a leadframe, some or all of which are disposed in the leadframe Semiconductor chips are also arranged after the LOC assembly of the module on a common, contiguous part of the wafer wafer.

From the DE 10 2004 039 903 B3 For example, an ultrasonic head unit is known, comprising an ultrasonic sonotrode for producing a transponder on a surface of a substrate.

From the DE 197 09 912 A1 For example, a method for ultrasonic bonding terminals of a semiconductor chip is known.

An object of the invention is to make the production of a possibly more robust semiconductor module easier and less expensive. A further object of the invention is to provide or use a simple and more cost-effective producible and more robust semiconductor module.

• – Bereitstellen zumindest eines Halbleiterchips aufweisend zumindest eine elektrische Halbleiterchip-Kontaktstelle,
• – Bereitstellen zumindest eines Leadframes aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – Herstellen einer jeweiligen Kontaktverbindung als Bond-Verbindung mittels Bonden,

wobei die jeweilige Kontaktverbindung eine der elektrischen Halbleiterchip-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet. A solution to the problems arises in a method of the type mentioned by the following method steps:

• Providing at least one semiconductor chip having at least one electrical semiconductor chip contact point,
• Providing at least one leadframe having at least one electrical leadframe contact point,
• Producing a respective contact connection as a bonding connection by means of bonding,

wherein the respective contact connection electrically connects one of the electrical semiconductor chip contact points with one of the electrical leadframe contact points.

• – Bereitstellen zumindest eines Substrates aufweisend zumindest eine elektrische Substrat-Kontaktstelle,
• – Bereitstellen zumindest eines Leadframes aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – Herstellen einer jeweiligen Kontaktverbindung als Bond-Verbindung mittels Bonden,

wobei die jeweilige Kontaktverbindung eine der elektrischen Substrat-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet. An alternative solution to the problems arises in a method of the type mentioned by the following method steps:

• Providing at least one substrate having at least one electrical substrate contact point,
• Providing at least one leadframe having at least one electrical leadframe contact point,
• Producing a respective contact connection as a bonding connection by means of bonding,

wherein the respective contact connection electrically connects one of the electrical substrate pads to one of the electrical leadframe pads.

• – zumindest einen Halbleiterchip aufweisend zumindest eine elektrische Halbleiterchip-Kontaktstelle,
• – zumindest einen Leadframe aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – eine jeweilige Kontaktverbindung, welche eine der elektrischen Halbleiterchip-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet,

wobei die jeweilige Kontaktverbindung als Bond-Verbindung ausgestaltet ist. Furthermore, a solution of the tasks in a semiconductor module of the type mentioned results in that the semiconductor module comprises:

• At least one semiconductor chip having at least one electrical semiconductor chip contact point,
• At least one leadframe having at least one electrical leadframe contact point,
• A respective contact connection which electrically connects one of the electrical semiconductor chip contact points to one of the electrical leadframe contact points,

wherein the respective contact connection is designed as a bond connection.

• – zumindest ein Substrat aufweisend zumindest eine elektrische Substrat-Kontaktstelle,
• – zumindest einen Leadframe aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – eine jeweilige Kontaktverbindung, welche eine der elektrischen Substrat-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet,

wobei die jeweilige Kontaktverbindung als Bond-Verbindung ausgestaltet ist. An alternative solution to the problems arises in a semiconductor module of the type mentioned above in that the semiconductor module has:

• At least one substrate having at least one electrical substrate contact point,
• At least one leadframe having at least one electrical leadframe contact point,
• A respective contact connection electrically connecting one of the electrical substrate pads to one of the leadframe electrical contact pads,

wherein the respective contact connection is designed as a bond connection.

Furthermore, a solution of the tasks in a power converter of the type mentioned results in that the power converter has at least one such semiconductor module.

Finally, a solution to the problems in a vehicle of the type mentioned results in that the vehicle has a drive train comprising at least one such converter.

In one of the proposed methods, at least one semiconductor chip and at least one leadframe are initially provided. In this case, a semiconductor chip is understood in particular to be a piece of a semiconductor wafer, that is to say a semiconductor chip with an integrated circuit possibly applied thereto. In English, the term "the" is common for a semiconductor chip. The respective semiconductor chip has at least one electrical semiconductor chip contact point, wherein the number of semiconductor chip contact points can also be greater or substantially greater. Thus, the stated number may well be in the range of a few tens or more semiconductor chip contact points.

In the alternative, proposed method, at least one substrate having at least one electrical substrate contact point is provided instead of the at least one semiconductor chip, wherein the number of substrate contact points can also be larger or substantially larger, so that also some tens or more substrate contact points are conceivable are. In this case, a substrate is understood in particular to be a ceramic carrier structure to which electrical conductor tracks and, if appropriate, a semiconductor chip are / are applied. Such support structures may be, for example, a DCB substrate (direct bonded copper) or an IMS (insulated metal substrate).

A leadframe is a "lead frame", that is to say a preferably metallic lead support, in particular in the form of a frame. The respective leadframe has at least one electrical leadframe contact point, wherein the number of leadframe contact points can also be greater or substantially greater, so that a few tens or more leadframe contact points are also conceivable. In particular, a leadframe has two or more mutually separate electrical conductor tracks.

According to one proposed method, it is provided that the respective contact connection of one of the electrical semiconductor chip contact points with one of the electrical leadframe contact points is produced as a bonding connection by means of bonding and thus an electrical connection is achieved. Accordingly, the proposed semiconductor module has a respective contact connection, which is designed as a bond connection. Bonding is a technique for the electrical contacting of micro-terminals of semiconductor chips. Bonding offers some advantages, such as not having to add heat to make the contact.

If one semiconductor chip and one leadframe are each provided for the semiconductor module, the number of leadframe contact points preferably corresponds to the number of bonded contact connections. For this case, the said number continues to correspond to the number of semiconductor chip contact points, apart from possible further connections of the semiconductor chip that are not connected to the leadframe. If two or more semiconductor chips or leadframes are provided, the number of semiconductor chip contact points, leadframe contact points or contact connections changes accordingly. Preferably, the majority, in particular all, of the respective leadframe contact points or of the respective semiconductor chip contact points is connected by means of a respective bonding connection to a respective semiconductor chip contact point or a respective leadframe contact point.

One idea of the present invention is therefore to simplify the contacting of semiconductor chips by means of leadframes by bonding them to the semiconductor chip. For example, the bonding of leadframes allows a process on a so-called "big map", ie in multiple use, whereby a comparatively low cycle time is given, so that costs can be saved. The use of leadframes further represents a planar chip contacting, whereby the typically associated advantages are also given, such as. B. a longer life by a greater robustness of the semiconductor module or a smaller volume requirement.

According to the other proposed method or semiconductor module is provided that the respective contact connection of one of the electrical substrate contact points with one of the electrical leadframe contact points is produced as a bonding connection by means of bonding or is and so an electrical connection is achieved. Accordingly, the proposed semiconductor module has a respective contact connection, which is designed as a bond connection. Very analogous considerations apply here as for the first proposed method or semiconductor module.

In an advantageous embodiment of the invention, the two previously explained methods or semiconductor modules are combined, wherein the respective leadframe has at least two electrical leadframe contact points.

This embodiment of the method or the semiconductor module thus provides at least a first electrical contact connection, which electrically connects a respective electrical semiconductor chip contact point with a respective electrical leadframe contact point, and at least one second electrical contact connection, which has a respective electrical substrate contact point with one electrically connects respective electrical leadframe contact points.

In a further advantageous embodiment of the invention, ultrasonic bonding is used to produce the respective contact connection or the respective contact connection is designed as an ultrasonic bonding connection.

In ultrasonic bonding, the respective leadframe contact points are pressed with a certain pressure onto the respective semiconductor chip or substrate contact point to be connected, ultrasonic vibrations being applied. The ultrasonic vibrations lead to diffusion processes between the material of the leadframe contact point and the material of the semiconductor chip or substrate contact point, resulting in a firm connection or cold welding of the two contact points.

By ultrasonic bonding, the respective contact connection can be made at a particularly low temperature, whereby the process is designed low energy and thus costs can be saved. In particular, further damage to the semiconductor chip or substrate can be avoided.

In a further advantageous embodiment of the invention, at least one sonotrode is used to produce the respective contact connection.

By means of the respective sonotrode, high-frequency mechanical oscillations, in particular ultrasound, can be applied to the respective semiconductor chip or substrate contact point and the respective leadframe contact point in order to produce the respective bond connection. Preferably, the respective sonotrode is used in conjunction with the above-described ultrasonic bonding.

In a further advantageous embodiment of the invention, a plurality of the contact connections are produced simultaneously by means of a respective sonotrode.

As explained above, at least two, but also more or substantially more than two leadframe contact points and thus bond connections can be provided for the proposed semiconductor module. By several or all of the proposed bond connections, so for example, at least two, some ten or more bond connections are made simultaneously by sonotrode, a connection process is provided, which significantly reduces the lead times and saves costs accordingly.

In particular, for example, all bond connections of the respective leadframe and / or all bond connections of the respective semiconductor chip or substrate, but also all bond connections of the semiconductor module or substrate can be produced simultaneously. It is conceivable that a particular sonotrode is used per manufactured bond connection, wherein a sonotrode for two or more of the simultaneously produced bond compounds can be used.

The simultaneous production of two or more bond connections means that the two or more bond connections are made at least partially overlapping in time. Thus, the simultaneous production of the considered, respective bond connections are understood to mean essentially parallel work steps and non-sequential work steps. Preferably, therefore, a process is provided at the beginning of the considered bond connections are not yet present, then substantially simultaneously the bond connections are made and the completion of the process, the production of all considered bond connections is completed. In particular, the proposed method or the proposed semiconductor module thus enables a parallelization of working steps, namely the contacting of the individual semiconductor chip or substrate contact points, whereby throughput times can be reduced and costs can be saved.

In a further advantageous embodiment of the invention, the respective leadframe is provided as a prefabricated leadframe.

The respective leadframe is preferably prepared in advance by means of stamping and thus provided piecewise for the proposed method. In particular, therefore, leadframes are not required, which are wound up on a roll, the roll being unwound during the production process of the semiconductor module in order to obtain the individual leadframes.

In a further advantageous embodiment of the invention, the respective semiconductor chip has an at least partially flat surface, wherein the semiconductor chip contact point provided for the respective contact connection is arranged on the surface of the respective semiconductor chip.

In the proposed embodiment, it is provided that the respective semiconductor chip has the semiconductor chip contact points provided for the bonding connection on an at least partially flat surface. In particular, said surface may be a chip top.

In particular, the respective semiconductor chip has a chip bottom side and a chip top side which lie substantially opposite one another. In this case, the chip can be arranged on its chip underside on a printed circuit board, wherein the chip has on its chip top side the explained semiconductor chip contact points. PCBs ("printed circuit board") or DCB ("direct-bonded copper") may be used as printed circuit boards, for example, onto which the particular semiconductor chip can be soldered, sintered or, for example, bonded by means of chip bonding.

It is of particular advantage in the present invention that the respective bond connections of at least one leadframe with at least one semiconductor chip are not accompanied by special requirements for the surface of the respective semiconductor chip, as would be present, for example, during soldering or sintering. In contrast, soldering or sintering for connecting a leadframe to a semiconductor chip requires special properties of the semiconductor chip surface. Thus, the proposed invention allows ordinary standard semiconductor chips used for the production of the proposed semiconductor module, so that therefore no increased effort must be operated as in particular during sintering or soldering. Thus, the present invention raises great potential for cost savings.

In a further advantageous embodiment of the invention, the respective semiconductor chip pad has aluminum, doped aluminum or an aluminum alloy.

Since the respective semiconductor chip comprises aluminum, doped aluminum or an aluminum alloy at its respective semiconductor chip pad, in particular ordinary standard semiconductor chips can be used for the proposed method or the proposed semiconductor module. As explained above, this results in great savings potential.

In a further advantageous embodiment of the invention, the respective semiconductor chip has at least two electrical semiconductor chip contact points, wherein the respective leadframe has at least two electrical leadframe contact points.

Preferably, the at least two electrical semiconductor chip contact points are arranged on the above-explained surface of the respective semiconductor chip. In particular, the at least two electrical semiconductor chip contact points are electrically connected to the at least two electrical leadframe contact points by means of a respective contact connection, as already explained above.

In a further advantageous embodiment of the invention, the respective leadframe has a width of a few tenths of a millimeter to a few centimeters.

Leadframes having a corresponding width are therefore used in particular in the proposed method or the proposed semiconductor module, and it is also possible to use a plurality of leadframes per semiconductor chip.

In particular, the proposed semiconductor module can be arranged in a power module, which furthermore has a printed circuit board, for example in the form of a PCB or DCB. As explained above, the respective semiconductor module can be connected to the circuit board by means of soldering, sintering or bonding, for example chip bonding.

Preferably, the power converter is designed for an electrical power of at least 10 kW, preferably 40-100 kW.

The vehicle is advantageously designed as a hybrid car or electric car.

In the following the invention will be described and explained in more detail with reference to the embodiments illustrated in the figures. Show it:

1 - 10 a first to ninth embodiment of the proposed semiconductor module,

11 a schematic representation of the proposed method,

12 a method step of an embodiment of the proposed method for producing a semiconductor module,

13 an embodiment of the proposed power converter, and

14 an embodiment of the proposed vehicle.

1 shows a first embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown.

The semiconductor module 1 has a semiconductor chip 2 with a semiconductor electrical chip pad 3 as well as a leadframe 4 with an electrical leadframe contact point 5 on. From the leadframe 4 only a section is shown, as at its right end in the 1 is indicated. Furthermore, the semiconductor module 1 a contact connection 6 on which the electrical semiconductor chip pad 3 with the electrical leadframe contact point 5 connects electrically. Here is the contact connection 6 designed as a bond connection.

2 shows a second embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown. Same reference numerals as in 1 denote the same objects.

The semiconductor module 1 has a substrate 12 with an electrical substrate pad 13 as well as a leadframe 4 with an electrical leadframe contact point 5 on. From the leadframe 4 is similar to in 1 only a section shown. Furthermore, the semiconductor module 1 a contact connection 6 on which is the electrical substrate pad 13 with the electrical leadframe contact point 5 connects electrically. Here is the contact connection 6 designed as a bond connection.

3 shows a third embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown.

The semiconductor module 1 has a substrate 12 with an electrical substrate pad 13 , a semiconductor chip 2 with a semiconductor electrical chip pad 3 as well as a leadframe 4 with two electrical leadframe contact points 5 on. In this case, the semiconductor chip 2 on the substrate 12 arranged.

The semiconductor module 1 has two contact connections 6 on, of which the one contact connection 6 the electrical semiconductor chip pad 3 with the one electrical leadframe contact point 5 electrically connects and of which the other contact connection 6 the electrical substrate pad 13 with the other electrical leadframe contact point 5 connects electrically. Here is the respective contact connection 6 designed as a bond connection.

4 shows a fourth embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown.

The semiconductor module 1 has a semiconductor chip 2 with two electrical semiconductor chip pads 3 as well as a leadframe 4 with two electrical leadframe contact points 5 on. From the leadframe 4 only a section is shown. Furthermore, the semiconductor module 1 two contact connections 6 each of which is one of the electrical semiconductor chip pads 3 with one of the electrical leadframe contact points 5 connects electrically. Here is the respective contact connection 6 designed as a bond connection.

5 shows a fifth embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown.

The fifth embodiment is quite similar to the fourth embodiment, so that only some differences will be explained below. The semiconductor chip 2 has a substantially flat surface 10 on, where for the respective contact connection 6 provided semiconductor chip pad 2 on the flat surface 10 is arranged.

Such a flat surface 10 can incidentally also in the other embodiments of the semiconductor module 1 with a semiconductor chip 2 for the respective semiconductor chip 2 be provided.

6 shows a sixth embodiment of the proposed semiconductor module 1 , wherein a plan view of the semiconductor module 1 is shown.

The semiconductor chip 2 in the present embodiment has six electrical semiconductor chip pads 3 on, where indicated by a dashed line leadframe 4 six corresponding electrical leadframe contact points 5 having. The respective contact points are by means of a respective contact connection 6 electrically connected to each other, wherein the respective contact connection 6 designed as a bond connection.

The leadframe 4 has a width 11 from a few tenths of a millimeter to a few centimeters.

The 7 and 8th show a seventh embodiment of the proposed semiconductor module 1 , where in 7 a cross section through the semiconductor module 1 and in 8th a plan view of the semiconductor module 1 is shown.

The semiconductor module 1 has a substrate 12 with an electrical substrate pad 13 , four semiconductor chips 2 each with an electrical semiconductor chip pad 3 as well as a leadframe 4 with five electrical leadframe contact points 5 on. In this case, the respective semiconductor chip 2 on the substrate 12 arranged. In 8th is the lead frame 4 indicated by a dashed line.

The semiconductor module 1 has a total of five contact connections 6 on, of which a first to fourth contact connection 6 the electrical semiconductor chip pad 3 of the first to fourth semiconductor chips 2 with the first to fourth leadframe electrical contact pads 5 connects electrically. The fifth contact connection 6 provides an electrical connection of the electrical substrate pad 13 with the fifth electrical leadframe contact point 5 ago. Here is the respective contact connection 6 designed as a bond connection.

The leadframe 4 has a width 11 from a few tenths of a millimeter to a few centimeters.

9 shows an eighth embodiment of the proposed semiconductor module 1 , wherein a plan view of the semiconductor module 1 is shown.

The semiconductor module 1 has a substrate 12 with eight semiconductor chips arranged thereon 2 each with an electrical semiconductor chip pad 3 as well as a leadframe 4 with multiple electrical leadframe contact points 5 on. The substrate 12 is largely due to the leadframe 4 obscured, which is indicated by the corresponding dashed line.

The semiconductor module 1 initially has eight contact connections 6 each of which has the electrical semiconductor chip pad 3 one of the eight mentioned semiconductor chips 2 with the respective electrical leadframe contact point 5 connects electrically. Here is the respective contact connection 6 designed as a bond connection. In addition, there are five more leadframe contact points 5 provided which of that area of the leadframe 4 in 9 led out to the right, which is the substrate 12 mostly covered.

Furthermore, there are four separation points 16 provided in 9 are indicated as dotted lines. At the separation points 16 can be the inner area of the leadframe 4 from the outer area of the leadframe 4 , For example, by means of punching or lasers, can be separated. For example. can be the outer area of the leadframe 4 serve the leadframe 4 during the manufacture of the semiconductor module 1 better transport or position, whereas the inner area of the leadframe 4 the actual, for the electrical contacts of the semiconductor module 1 required part of the leadframe 4 represents.

10 shows a ninth embodiment of the proposed semiconductor module 1 wherein a cross section through the semiconductor module 1 is shown. For clarity, the respective electrical contact points in 10 not shown.

The semiconductor module 1 has a module housing 15 with a heat sink 14 and two on the heat sink 14 arranged substrates 12 on. On the in 10 left illustrated substrate 12 are two semiconductor chips 2 arranged and on the in 10 right substrate 12 is a semiconductor chip 2 arranged. As in 10 are shown, the semiconductor chips 2 partly with each other and partly with one of the substrates 12 electrically via respective contact connections 6 and a respective leadframe 4 electrically connected, further comprising two further contact connections 6 and another leadframe 4 for electrical connection of the two substrates 12 are provided. The leadframes 4 can, as in 10 indicated and starting from the substrate 12 or the respective semiconductor chip 2 , be arranged one above the other or even next to each other, in particular at the same height, be arranged.

In the exemplary embodiments explained above, the respective semiconductor chip contact point 3 For example, aluminum, doped aluminum or an aluminum alloy. Alternatively or additionally, the respective contact connection 6 be designed as an ultrasonic bonding connection. The respective leadframe 4 in particular, a width 11 preferably from a few tenths of a millimeter to a few centimeters.

11 shows a schematic representation of the proposed method for producing a semiconductor module 1 ,

In method step S1, at least one semiconductor chip is formed 2 and / or a substrate 12 provided, the or each at least one electrical semiconductor chip pad 3 or substrate contact point 13 having.

In method step S2, at least one lead frame 4 provided, each having at least one electrical lead frame contact point 5 having.

In method step S3, a respective contact connection is made 6 manufactured as a bonding connection by means of bonding, wherein the respective contact connection 6 the at least one electrical semiconductor chip pad 3 or the at least one electrical substrate pad 13 with one of the electrical leadframe contact points 5 connects electrically.

For the preparation of the respective contact connection 6 For example, ultrasonic bonding can be used, including in particular a respective sonotrode 7 can be used as in 7 is shown. Preferably, more of the contact connections 6 simultaneously by means of a respective sonotrode 7 produced. In particular, the respective leadframe 4 as a prefabricated leadframe 4 to be provided.

12 shows a method step of an embodiment of the proposed method, applied to the fourth embodiment of the proposed semiconductor module 1 ,

The two contact connections 6 are each prepared as a bond connection by means of ultrasonic bonding, for which purpose a respective sonotrode 7 is used. Preferably, the two contact connections 6 simultaneously by means of the two sonotrodes 7 produced.

The explained method step can also be used correspondingly for the third and fifth to eighth embodiments, to two or more of the contact connections 6 especially simultaneously.

13 shows an embodiment of the proposed power converter 8th which the proposed semiconductor module 1 and preferably for a drive train of a vehicle 9 is designed.

14 shows an embodiment of the proposed vehicle 9 which the proposed power converter 11 has in its drive train and is preferably designed as a hybrid or electric vehicle.

In summary, the invention relates to two methods for producing a semiconductor module. Furthermore, the invention relates to two such semiconductor modules, in particular for a power converter of a drive train of a vehicle. Furthermore, the invention relates to a power converter, in particular for a drive train of a vehicle, comprising at least one such semiconductor module. Finally, the invention relates to a vehicle, in particular hybrid or electric vehicle, comprising a drive train comprising such a power converter.

• – Bereitstellen zumindest eines Halbleiterchips aufweisend zumindest eine elektrische Halbleiterchip-Kontaktstelle,
• – Bereitstellen zumindest eines Leadframes aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – Herstellen einer jeweiligen Kontaktverbindung als Bond-Verbindung mittels Bonden,

wobei die jeweilige Kontaktverbindung eine der elektrischen Halbleiterchip-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet. In order to make the production of such a semiconductor module simpler and more cost-effective or to provide or use a simple and less expensive semiconductor module that can be produced, the following method steps are proposed:

• Providing at least one semiconductor chip having at least one electrical semiconductor chip contact point,
• Providing at least one leadframe having at least one electrical leadframe contact point,
• Producing a respective contact connection as a bonding connection by means of bonding,

wherein the respective contact connection electrically connects one of the electrical semiconductor chip contact points with one of the electrical leadframe contact points.

• – Bereitstellen zumindest eines Substrates aufweisend zumindest eine elektrische Substrat-Kontaktstelle,
• – Bereitstellen zumindest eines Leadframes aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – Herstellen einer jeweiligen Kontaktverbindung als Bond-Verbindung mittels Bonden,

wobei die jeweilige Kontaktverbindung eine der elektrischen Substrat-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet. Alternatively proposed the following method steps:

• Providing at least one substrate having at least one electrical substrate contact point,
• Providing at least one leadframe having at least one electrical leadframe contact point,
• Producing a respective contact connection as a bonding connection by means of bonding,

wherein the respective contact connection electrically connects one of the electrical substrate pads to one of the electrical leadframe pads.

• – zumindest einen Halbleiterchip aufweisend zumindest eine elektrische Halbleiterchip-Kontaktstelle,
• – zumindest einen Leadframe aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – eine jeweilige Kontaktverbindung, welche eine der elektrischen Halbleiterchip-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet,

wobei die jeweilige Kontaktverbindung als Bond-Verbindung ausgestaltet ist. Furthermore, it is proposed that the semiconductor module has:

• At least one semiconductor chip having at least one electrical semiconductor chip contact point,
• At least one leadframe having at least one electrical leadframe contact point,
• A respective contact connection which electrically connects one of the electrical semiconductor chip contact points to one of the electrical leadframe contact points,

wherein the respective contact connection is designed as a bond connection.

• – zumindest ein Substrat aufweisend zumindest eine elektrische Substrat-Kontaktstelle,
• – zumindest einen Leadframe aufweisend zumindest eine elektrische Leadframe-Kontaktstelle,
• – eine jeweilige Kontaktverbindung, welche eine der elektrischen Substrat-Kontaktstellen mit einer der elektrischen Leadframe-Kontaktstellen elektrisch verbindet,

wobei die jeweilige Kontaktverbindung als Bond-Verbindung ausgestaltet ist. Alternatively, it is proposed that the semiconductor module comprises:

• At least one substrate having at least one electrical substrate contact point,
• At least one leadframe having at least one electrical leadframe contact point,
• A respective contact connection electrically connecting one of the electrical substrate pads to one of the leadframe electrical contact pads,

wherein the respective contact connection is designed as a bond connection.

Furthermore, a corresponding power converter and a corresponding vehicle are proposed.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19927747 C1 [0006]
• DE 102004039903 B3 [0007]
• DE 19709912 A1 [0008]

Claims (17)

Method for producing a semiconductor module ( 1 ) comprising the following method steps: - providing at least one semiconductor chip ( 2 ) comprising at least one electrical semiconductor chip pad ( 3 ), - providing at least one leadframe ( 4 ) comprising at least one electrical leadframe contact point ( 5 ), - establishing a respective contact connection ( 6 ) as a bond connection by means of bonding, wherein the respective contact connection ( 6 ) one of the electrical semiconductor chip contact points ( 3 ) with one of the electrical leadframe contact points ( 5 ) electrically connects. Method for producing a semiconductor module ( 1 ) comprising the following method steps: providing at least one substrate ( 12 ) comprising at least one electrical substrate pad ( 13 ), - providing at least one leadframe ( 4 ) comprising at least one electrical leadframe contact point ( 5 ), - establishing a respective contact connection ( 6 ) as a bond connection by means of bonding, wherein the respective contact connection ( 6 ) one of the electrical substrate pads ( 13 ) with one of the electrical leadframe contact points ( 5 ) electrically connects. Method according to claims 1 and 2, wherein the respective leadframe ( 4 ) at least two electrical leadframe contact points ( 5 ) having. Method according to one of the preceding claims, wherein for the preparation of the respective contact compound ( 6 ) Ultrasonic bonding is used. Method according to one of the preceding claims, wherein for the preparation of the respective contact compound ( 6 ) at least one sonotrode ( 7 ) is used. Method according to one of the preceding claims, wherein a plurality of the contact compounds ( 6 ) simultaneously by means of a respective sonotrode ( 7 ) getting produced. Method according to one of the preceding claims, wherein the respective leadframe ( 4 ) as a prefabricated leadframe ( 4 ) provided. Semiconductor module ( 1 ), in particular for a power converter ( 8th ) of a drive train of a vehicle ( 9 ), wherein the semiconductor module ( 1 ): - at least one semiconductor chip ( 2 ) comprising at least one electrical semiconductor chip pad ( 3 ), - at least one leadframe ( 4 ) comprising at least one electrical leadframe contact point ( 5 ), - a respective contact connection ( 6 ), which one of the electrical semiconductor chip contact points ( 3 ) with one of the electrical leadframe contact points ( 5 ) electrically connects, wherein the respective contact connection ( 6 ) is designed as a bond connection. Semiconductor module ( 1 ), in particular for a power converter ( 8th ) of a drive train of a vehicle ( 9 ), wherein the semiconductor module ( 1 ): - at least one substrate ( 12 ) comprising at least one electrical substrate pad ( 3 ), - at least one leadframe ( 4 ) comprising at least one electrical leadframe contact point ( 5 ), - a respective contact connection ( 6 ), which one of the electrical substrate pads ( 13 ) with one of the electrical leadframe contact points ( 5 ) electrically connects, wherein the respective contact connection ( 6 ) is designed as a bond connection. Semiconductor module ( 1 ) according to claims 8 and 9, wherein the respective leadframe ( 4 ) at least two electrical leadframe contact points ( 5 ) having. Semiconductor module ( 1 ) according to claim 8 or 10, wherein the respective semiconductor chip ( 2 ) an at least partially flat surface ( 10 ), wherein for the respective contact connection ( 6 ) provided semiconductor chip pad ( 3 ) on the surface ( 10 ) of the respective semiconductor chip ( 2 ) is arranged. Semiconductor module ( 1 ) according to claim 8, 10 or 11, wherein the respective semiconductor chip contact point ( 3 ) Aluminum, doped aluminum or an aluminum alloy. Semiconductor module ( 1 ) according to one of claims 8, 10, 11 or 12, wherein the respective semiconductor chip ( 2 ) at least two electrical semiconductor chip pads ( 3 ), wherein the respective leadframe ( 4 ) at least two electrical leadframe contact points ( 5 ) having. Semiconductor module ( 1 ) according to one of claims 8 to 13, wherein the respective contact connection ( 6 ) is designed as an ultrasonic bonding connection. Semiconductor module ( 1 ) according to one of claims 8 to 14, wherein the respective leadframe ( 4 ) a width ( 11 ) of at least a few tenths of a millimeter to a few centimeters. Power converter ( 8th ), in particular for a drive train of a vehicle ( 9 ), comprising at least one semiconductor module ( 1 ) according to one of claims 8 to 15. Vehicle ( 9 ), in particular hybrid or electric vehicle, comprising a drive train comprising at least one power converter ( 11 ) according to claim 16.

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