Abstract:
The invention relates to a method for producing an electronic circuit. According to said method, two semiconductor chips ( 46 ) with essentially the same structure are mounted on a surface ( 13 ) pertaining to a first conductor carrier ( 10 ) and coated with strip conductors ( 16 ). Said two semiconductor chips ( 46 ) comprise a first surface ( 49 ) and a second surface ( 58 ), one semiconductor chip ( 46 ) being mounted on the conductor carrier surface ( 13 ) with the first surface ( 49 ) thereof, and the other semiconductor chip ( 46 ) being mounted on the conductor carrier surface ( 13 ) with the second surface ( 58 ) thereof. The second surface ( 58 ) of the first semiconductor chip ( 46 ) and the first surface ( 49 ) of the other semiconductor chip ( 46 ) are interconnected by a lead frame ( 64 ) with an A.C. power supply ( 31 ).

Description:
CROSS-REFERENCE TO A RELATED APPLICATION 
   The invention described and claimed hereinbelow is also described in German Patent Application DE 10 2004 063 851.9 filed on Dec. 30, 2004. This German Patent Application provides the basis for a claim of priority of invention under 35 U.S.C. 119(a)-(d). 
   BACKGROUND OF THE INVENTION 
   In electronic control devices, the unhoused semiconductors are soldered—with increased power loss—together with a few passive components on a power substrate designed for a specific application. The preferred substrate material currently in use is a DBC (direct bonded copper) ceramic substrate. The power semiconductor components are soldered onto it. The source and drain connections of the power semiconductors are then contacted with the strip conductors of the power substrate using aluminum thick wire bond connections. The connections with the plastic-coated parts of the control device housing to be inserted are also created using thick aluminum wire bonds. Multiple bonds are typically required in order to conduct the current intensities required for specific applications. When this assembly technique is used, the only way to release the dissipation heat produced in the power semiconductors is via the underside of the chip. 
   The thick aluminum wire bonds described above have the following two disadvantages: A particularly large number of bonds is required, and they must be formed in succession. As a result, this portion of the manufacturing procedure is particularly time-consuming. A further disadvantage of these thick aluminum wire bonds is that they have limited capability of dissipating heat from the power semiconductors. 
   SUMMARY OF THE INVENTION 
   The inventive method has the advantage that the two semiconductor chips are interconnected by a lead frame on the side opposite to the conductor surface and, therefore, heat can be dissipated particularly well via this lead frame. A further advantage is that the connection of the lead frame with the two semiconductor chips can be created using a soldering process. This soldering process corresponds to the connection method used to connect the chips to the strip conductors of the first conductor carrier. Therefore, the chips are connected with the strip conductors and the lead frame is connected with the semiconductor chips in the same method step. This saves time, because the complicated bonding step is eliminated, and improved heat dissipation is achieved, since the lead frame conducts the heat particularly well. 
   According to a further embodiment of the present invention, it is provided that, immediately after the lead frame is mounted on the semiconductor chips, connections that serve no purpose in the circuit (i.e., short circuits) result between various contact points. Connections of this type are intended to mean that these connections would result in short-circuits during operation of the electronic circuit. Accordingly, it is provided in a further step of the present invention that the connections that serve no purpose in the circuit, i.e., the short-circuit connections, are severed in a subsequent step. 
   To ensure that the lead frame rests securely on the first conductor carrier over a particularly large surface area, it is provided that the lead frame is supported on support points that are not integrated in the electronic circuit. 
   A lead frame can be manufactured particularly easily when it is designed as a metallic punched grid. Particularly good compatibility of the lead frame with the coated first conductor carrier is given when the lead frame—like the first conductor carrier—is composed of a second conductor carrier coated with strip conductors. The first and second conductor carriers can be made of the same material, for example. 
   To ensure good adhesion and a good connection between the strip conductors on the first conductor carrier and the semiconductor chips, it is provided that the source and gate connections located on the second surfaces of the semiconductor chips are metallized before they are positioned on the first conductor carrier. 
   An exemplary embodiment of the inventive method is shown in the drawing. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a schematic depiction of the method for manufacturing the electronic circuit, 
       FIGS. 2 through 8  are top views of a first conductor carrier after certain method steps have been carried out. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENT 
   A flow chart of the manufacturing method is shown schematically in  FIG. 1 . The sequence of steps in the method depicted in  FIG. 1  is described in greater detail with reference to  FIGS. 2 through 7 . 
     FIG. 2  shows a first conductor carrier, which is designed as a DBC ceramic substrate in this case. On its surface  13 , conductor carrier  10  has non-conductive areas and conductive areas, which are referred to here as strip conductors  16 . Strip conductors  16  shown in  FIG. 2  serve various purposes in this case. The region furthest to the right will eventually serve as a negative connection  19 . A strip conductor  16  extends as one piece—designed as a “negative sense line”  22 —out of negative connection  19 , the remainder of which has a relatively large surface area. A strip conductor  16  that will eventually serve as positive connection  25  is located opposite to negative connection  19 . A “positive sense line”  28  extends out of connection  25 . A strip conductor  16  that serves as an A.C. power supply connection  31  is also shown on the surface of conductor carrier  10 . Located on one side of A.C. power supply connection  31  is a “gate  1 ” connection  34 , and, on the right-hand side, a “gate  2 ” connection  37 , designed as strip conductors  16 . In this case, two support surfaces  40  are also located on surface  13  of conductor carrier  10 . Support surfaces  40  serve initially only as strip conductors  16 , but they are electrically isolated from the other strip conductors. 
   A soldering paste is applied to the surface of a first conductor carrier  10 —which has been prepared accordingly—in step B 1  (see  FIG. 1 ), i.e., to selected surface regions of strip conductors  16 . Soldering paste  43  can be applied to the surface using screen printing. After first step B 1 , soldering paste  43  is located on support surfaces  40 , negative connection  19 , positive connection  25 , gate  1  connection  34 , gate  2  connection  37 , and A.C. power supply connection  31 . A side view of semiconductor chip  46  is shown in  FIG. 4   a . Semiconductor chip  46  has two surfaces: First surface  49  is the surface on which gate connection  52  and source connection  55  are located. Second surface  58  is the surface opposite to first surface  49 . Second surface  58  also carries drain connection  61 . According to  FIG. 1 , method step A 1  is also used on a semiconductor  46  of this type. In so doing, source connection  55  and gate connection  52  are provided with “under-bond metallization”. According to step B 2 ,  FIG. 1 , two semiconductor chips  46  are now placed on certain strip conductors  16  of conductor carrier  10 . A first semiconductor chip  46  is placed—via its second surface  58 —on positive connection  25  or in the region of positive connection  25 , which is covered with soldering paste  43 . First semiconductor  46  now faces away from surface  13  with gate connection  52  and source connection  55 . 
   Positive connection  25  is depicted as a straight, wide strip conductor  16  in  FIGS. 2 ,  3  and  4   b . Gate  1  connection  34 , which is also designed as strip conductor  16 , extends at a right angle to positive connection  25 . Gate  1  connection  34  extends at a right angle into the vicinity of the boundary of positive connection  25 . A support surface  40 , the surface of gate  1  connection  34  coated with soldering paste  43 , and gate connection  52  of semiconductor  46  lying on positive connection  25  lie on a line in this exemplary embodiment. The other semiconductor  46  lies with its source connection  55  on the region of negative connection  19  coated with soldering paste  43 . Gate connection  52  of second semiconductor  46  lies on gate  2  connection  37  or the region of gate  2  connection  37  coated with soldering paste  43 . 
   A top view of a lead frame  64  is shown in  FIG. 5   a . In the example, lead frame  64  shown in  FIG. 5   a  is a punched grid that has been punched out of a metal plate, e.g., a copper plate. According to method step C 1 ,  FIG. 1 , a layer of soldering paste  43  is applied to lead frame  64  on the side that will come in contact with semiconductors  46 . Soldering paste  43  is also applied using screen printing, for example. In a reflow soldering step (C 2 ), soldering paste  43  is liquified and then hardened via cooling. In an optional intermediate step C 3 , several connected lead frames  64  can be separated. This applies when lead frames  64  are punched out of one large, continuous plate. This separation is carried out, e.g., by punching away or severing the segments that connect adjacent lead frames  64 . For the case when certain sections of lead frame  64  are designed to eventually extend with marked elevation across strip conductors  16  of conductor carrier  10 , individual sections of lead frame  64  can be punched, so that these particular individual sections extend over individual connecting points in the manner of bridges. In a further method step C 5 , which typically follows one of the steps described above, lead frame  64 —with soldering paste  53  on the top—is flipped over. With soldering paste  43  now facing downward, lead frame  64  is immersed briefly in flux (step C 5 ). 
   Lead frame shown in  FIG. 5   a  has various sections. For example, lead frame  64  initially has a frame  67  that is actually closed overall and is annular in shape. Windows  70  are located in frame  67 , and are positioned such that various segments  73  remain. For example, a segment  73 . 1  is provided to eventually interconnect a support surface  40 , a gate connection  52 , and gate  1  connection  34 . A connector  76  located in the middle of frame  64  will eventually serve to connect a source connection  55  with a drain connection  61  and A.C. power supply connection  31 . A further connector  73 . 2 , located between frame  67  and connector  76 , will eventually serve only to connect connector  76  with a support surface  40  in a manner such that connector  76  is supported well over the individual electronic components. In a further step B 3 , lead frame  64  shown in  FIG. 5   a  is placed on conductor carrier  10 —which has been prepared in a suitable manner—thereby resulting in the connection points described above. In a further step B 4 , lead frame  64 —which, ideally, has been specially coated with soldering paste  43  only on the contact points—is joined in a vacuum soldering step with the strip conductors and the various connections of semiconductors  46 . In an optional further step B 5 , surface  13 —which may have become slightly contaminated during soldering—is cleaned. 
   In method step B 6  (see  FIG. 7 ), connectors  73  are separated at the appropriate points, which are connections that serve no purpose in the circuit. Separation points  79  are shown in  FIG. 7 . In the final step, the part of lead frame  64  that is no longer required is removed. The finished circuit is shown in  FIG. 8 . 
   As an alternative to a lead frame made of a metal plate as described with reference to the previous figures, the lead frame can also be composed of a flat ceramic conductor carrier. With a conductor carrier of this type, solderable layers would only be applied, e.g., to the region of T-shaped connector  76  (see  FIG. 5   a ) and connector  73 . 1 , and a small section of connector  73 . 2  in the region of support surfaces  40 . 
   In this case, semiconductor  46  shown on the right side in  FIG. 4   b  would be one of two semiconductor chips  46  that would be mounted on conductor carrier  10  using the flip chip technique. The electronic circuit shown in the figures described above is an H-bridge circuit, which is provided to control electrical motors. 
   Lead frame  64 —as a metallic, preferably copper connecting bridge—can be optimized in terms of thermomechanics, e.g., via the additional embossing described above, or by using suitable slots. For instance, this copper connecting bridge could connect the connections of the two transistors or semiconductors  46  in the shape of an omega. 
   In the steps described above, a method for manufacturing an electronic circuit is described, with which two semiconductor chips  46  are mounted on a surface  13  of a first conductor carrier  10  coated with strip conductors  16 . Semiconductor chips  46  have essentially the same structure. Both semiconductor chips  46  have a first surface  49  and a second surface  58 . One semiconductor chip  46 —via its first surface  49 —and the other semiconductor chip  46 —via its second surface  58 —are mounted on surface  13  of conductor carrier  10 . Second surface  58  of the one semiconductor chip  46  and first surface  49  of the other semiconductor chip  46  are interconnected by a lead frame  64  with an A.C. power supply connection  31 . It is also provided that, immediately after lead frame  64  is mounted on the semiconductor chips, connections  73  that serve no purpose in the circuit (i.e., short circuits) result between various contact points. In a subsequent step, the connections that serve no purpose in the circuit are severed. To obtain a lead frame  64  that is particularly resistant to vibration, it is provided that lead frame  64  is supported on support points  40  that are not integrated in the electronic circuit. 
   Lead frame  64  can be realized via two different possibilities: Using a metallic punched grid, which is preferably composed of copper, or using a second conductor carrier that is composed of insulating material—preferably ceramic, like conductor carrier  10 —and is coated with strip conductors  16 . It is provided that source connections  55  and gate connections  52  located on first surfaces  49  of semiconductor chips  64  are metallized before they are positioned on first conductor carrier  10 .