DE19648492A1 - Three=dimensional multi-chip module, e.g. memory module - Google Patents

Abstract

The internal circuit board (19) carries chips (20,21) on both sides with wire bonds (22) between the connection surfaces. The module is protected from mechanical stress and chemical attack by e.g. plastic encapsulant in a housing (23) from which pins (24,25) protrude for soldering to an external circuit board (26). The connections to the chips may be made alternatively by metallisation on their edges or undersides soldered directly to the surfaces of the internal circuit board, giving a lower profile.

Description

The invention relates to a multi-chip module according to the Ober Concept of claim 1.

Such a multi-chip module (MCM) is, for example, out the essay "Memory of the 3rd Dimension" by Henning Wriedt, published in "electronics industry" 10-1995, pages 100 and 102, known. Under the 3rd dimension there is the over stack of unsealed memory chips, their Circuit parts are each essentially two-dimensional are arranged side by side, understood. This technique is particularly interesting when an electronic circuit should take up little space. For example, four Memory chips in one level and four levels one on top of the other arranged in a 3D module. In addition there are two gold and three layers of insulation. The electrical connections between the individual levels take place along the Layer edges. The disadvantage of this stack structure is that Chip an intermediate layer with insulating and gold layers is such. This has a negative effect on the overall height of the Multi-chip module.

From DE 44 22 669 A1 is a multi-layer circuit board, the can be equipped with integrated circuits, is known. This Multi-layer printed circuit board has a wiring layer several wiring layers, each with a rage are separated from insulating material. The insulating layer  is with cutouts for connecting certain lines Provide wiring layers. Two essentially flat trained layers of electrically conductive material separated from each other by a thin dielectric layer and act as a backup capacitor for the supply voltage In the wiring layer are screen printed resist stands integrated. This is a production of low-rise buildings groups with high packing density possible.

The invention has for its object a multi-chip module to create, in which a further increase in Packing density is reached.

The new multi-chip module from type mentioned in the characterizing part of the An claim 1 mentioned features. In the subclaims are Described advantageous developments of the multi-chip module ben.

The invention has the advantage that for two semiconductor construction elements only an intermediate layer for the production of the electrical connections between the terminals of the half conductor components and the connections of the multi-chip module is required. The number of intermediate layers is compared the well-known stack structure, in which for each layer of An intermediate layer can be provided for semiconductor components had to cut in half. The construction is thus advantageous height of the multi-chip module is reduced. With a multi-layer top surface wiring of the circuit board, in which a ver Wire layer of at least two wiring layers and  a layer of insulating material, which the separates the two wiring layers from each other and only to the Has recesses at which connections between lines of the wiring layers are to be produced moreover, in a particularly advantageous manner, a thin structure of the internal circuit board. In the event that a high Power loss of the semiconductor components are dissipated must, a layer of good thermal conductivity in the circuit board the material. It can be advantageous continuous contacts are dispensed with if An closing elements used for the electrical connection of lines the internal circuit board with pads on the exter NEN PCB are required on the edge of the internal Printed circuit board arranged and designed such that they encompass these and establish an electrical connection between Lines on the top and bottom of the internal circuit board produce. Through these connection elements, the waste heat can one emitted into the environment and the other into the external circuit board on which the multi-chip module be pieces is derived. The shape is subject to the Connection elements and the type of their connection with the An end faces of the external circuit board no restrictions kungen. By using an internal circuit board with Multi-layer surface wiring is also a line spacing controllable, as in connection elements of semiconductors components are common. Passive components, such as B. Decoupling capacitors and resistors can be used in the PCB to be integrated.

Using the drawings, in which embodiments of the Invention are shown below, the invention as well as configurations and advantages explained in more detail.

Show it:

Fig. 1 is an internal circuit board with connection elements,

Fig. 2 is a multi-chip module with an internal circuit board equipped with semiconductor components on both sides and

Fig. 3 shows a multi-chip module with two internal circuit boards equipped with semiconductor components on both sides in an exploded view.

In a sectional view of FIG. 1, the layer structure of an internal circuit board is clearly visible. This essentially consists of a carrier substrate 1 , on the top and bottom of which a wiring layer is applied. The wiring layer on the top for example is built with three wiring layers 2 , 3 and 4 , which are separated by two layers of an electrically insulating dielectric 5 and 6 from each other. At the points where connections between lines of different wiring layers, for example a connection 7 between a line of the wiring layer 3 and a line of the wiring layer 4 , are to be produced, recesses are provided in the respective dielectric. Such a wiring layer can be made very thin and with fine structures. Further details on the manufacturing process can be found in the aforementioned DE 44 22 669 A1. The top of the wiring layer is covered with solder resist 8 , which has openings 9 on the connection surfaces for the connection elements of a semiconductor component to be populated. These openings 9 also serve as a solder depot, ie as a space in which a solder can be brought in. Vias 10 in the carrier substrate 1 serve both for the electrical connection of lines of the upper and lower wiring layers and for heat coupling between the semiconductor component to be populated on the upper side and the lower side. At the edges of the internal circuit board connection elements 11 and 12 are arranged, which encompass the edges and an electrical connection between connection surfaces 13 and 14 of the upper side and connection surfaces 15 and 16 of the underside. As a result, the number of required plated through holes 10 in the carrier substrate 1 can be reduced. Another function of the connection elements 11 and 12 is the dissipation of the waste heat generated in the multi-chip module via pins 17 and 18 , respectively, which are J-shaped here, into the external circuit board on which the multi-chip module is mounted becomes. At the same time, the connection elements 11 and 12 themselves serve as heat sinks with their pins 17 and 18, respectively.

It should be noted that Fig. 1 is not drawn to scale. The thickness of the individual layers is increased significantly in relation to the width only for the sake of clarity.

Functions of the carrier substrate 1 are essentially an increase in the stability of the internal circuit board and an improvement in heat dissipation to the connection elements 11 and 12 . If lower requirements are placed on stability by the methods used to manufacture the multi-chip module or by its handling, then a carrier substrate can also be dispensed with. The carrier substrate can also be replaced by a layer of good heat-conducting material, for example metal. This has an advantageous effect on the thickness of the internal circuit board and thus on the overall height of the multi-chip module with such a circuit board.

As shown in the sectional view according to FIG. 2, an internal printed circuit board 19 is equipped with a semiconductor component 20 and 21 both on its upper side and on its lower side. The electrical connections between the connection surfaces of the semiconductor components and connection surfaces on the internal circuit board 19 are produced by bonding with bond wires 22 . The multi-chip module is protected in a housing 23 from a potting compound, for example from plastic, against mechanical and chemical stresses. Pins 24 and 25 protrude from the housing 23 , which are electrically connected by solder to an external circuit board 26 on which the multi-chip module is mounted. If only low demands are placed on protection against environmental influences, the housing can also be designed to be open and, for example, to serve as a support frame or to be omitted entirely.

As an alternative to the bond wiring shown in Fig. 2, pads of semiconductor devices can also be performed as metallization, which are located on the edges or on the underside of the semiconductor device, which faces the internal printed circuit board in the assembled state, and directly with pads of the internal PCB are soldered. This embodiment is characterized by a lower overall height since no space is required for the bonding wiring.

In the exploded view according to FIG. 3, two internal circuit boards 27 and 28 , which are equipped with semiconductor components 29 , 30 and 31 , 32 on both sides, are arranged one above the other. Below this there is a printed circuit board 33 on which the fully assembled multi-chip module can be fitted. The semiconductor components 29 . . . 32 are provided with connection elements, which are designed as metallization of the semi-conductor material. In Fig. 3 only some connection elements of the semiconductor components 29 and 31 , for example a connection element 34 , are visible. The internal circuit boards 27 and 28 have for this purpose corresponding pads 35 , which are filled with solder, so that the semiconductor components 29th . . 32 can be soldered directly to the internal circuit boards 27 and 28 . Through contacts 36 are used for heat coupling the semiconductor devices 29th . . 32 over the internal printed circuit boards 27 and 28 so that any waste heat generated in one of the semiconductor components 29 , 30 , 31 or 32 is distributed evenly over the component stack and does not lead to selective heating. The printed circuit boards 27 and 28 are provided with internal metal layers for cooling and thus both contribute to cooling the component stack. For a further improvement of the heat coupling, the contacts 36 can also be filled with a heat conductor, in particular a thermal paste. For an electrical and heat-conducting connection, the internal printed circuit board 28 is provided with connection elements 37 , which are soldered to the correct sponding connection surfaces 38 on the internal printed circuit board 27 . Likewise, along the edges of the internal printed circuit board 27, connection elements 39 are arranged, which are soldered to connection surfaces 40 of the external printed circuit board 33 .

In another embodiment, not shown in the figures The connection elements can form one above the other ordered internal circuit boards also vertically aligned be placed so that the connection elements are adjacent internal circuit boards are soldered directly to one another. This design is particularly useful when the same Semiconductor devices are stacked in this way same internal circuit boards for the different levels can be used.

As an alternative to the embodiment shown in FIG. 3, instead of the plated-through holes for heat coupling, a recess can also be seen in the internal printed circuit boards, which essentially takes up the space between the connection surfaces 35 and is filled with a good heat-conducting material, for example a metal plate .

The new stack structure of a multi-chip module allows in advantageously also on the top of the multi-chip module to arrange a heat sink, the thermal with the Component stack is coupled.  

Advantageous to heat dissipation via the connection elements of the multi-chip module acts towards the external circuit board the small thickness of the wiring layer, which are the connection elements of those within the internal Printed circuit board embedded metal layers electrically isolated. The wiring layers with a lower thermal conductivity ability thus represents a comparatively short path for the waste heat and hardly reduce the excess closing elements transferable heat flow.

In another design deviating from FIG. 3, upper internal printed circuit boards can also be made larger than lower ones and can be provided with longer connection elements which project laterally beyond the lower internal printed circuit boards and are soldered directly to the external printed circuit board. The arrangement of the connection areas on an external printed circuit board then resembles a grid with several connection rows.

For equipping the internal circuit boards on both sides these should be carried out in multiple layers, so that the same Semiconductor components the mirror image arrangement of the Component connections on a common connection diagram for the multi-chip module can be returned.

The new multi-chip module is due to its high packing density, for example, in the following applications partially applicable:

• Sound and / or image carriers with semiconductor memories,
• - RAM for personal computers or
• - Memory on PCMCIA cards.

Claims (9)

1. Multi-chip module, which is designed for mounting on a circuit board, characterized by at least one internal, on both sides with semiconductor components ( 20 , 21 ) be populated circuit board ( 19 ). 2. Multi-chip module according to claim 1, characterized in that the semiconductor components ( 20 , 21 ) by bond wire ( 22 ) are connected to pads on the internal circuit board ( 19 ). 3. Multi-chip module according to claim 1, characterized in that the semiconductor components ( 29 ... 32 ) are provided with connection elements ( 34 ) which are designed as metallization of the semiconductor material and directly with connection surfaces ( 35 ) on the internal PCB ( 27 , 28 ) are soldered. 4. Multi-chip module according to one of the preceding claims, characterized in that connection elements ( 11 , 12 ) for the electrical connection of lines of the internal printed circuit board with connection surfaces on the external printed circuit board are arranged at the edge of the internal printed circuit board and are formed in such a way, that they encompass these and electrical connections between the lines of the top and bottom of the internal circuit board can be produced by the connecting elements. 5. Multi-chip module according to claim 4, characterized records that the internal circuit board has at least one layer has good heat-conducting material, which is essentially Lichen extends over the surface of the internal circuit board. 6. Multi-chip module according to claim 5, characterized in that the internal circuit board ( 27 , 28 ) with through contacts ( 36 ) to produce a good heat-conducting connection between the semiconductor components ( 29 ... 32 ) and the location good heat-conducting material. 7. Multi-chip module according to one of the preceding claims, characterized in that in a housing above and / or below the first internal circuit board ( 27 ) further, with semiconductor components ( 31 , 32 ) equipped Lei terplatten ( 28 ) are arranged. 8. Multi-chip module according to claim 7, characterized in that connection elements ( 37 ) for the electrical connection of lines Ver the further internal circuit boards ( 28 ) with connection surfaces ( 38 ) on the first internal circuit board ( 27 ) arranged in the housing are. 9. Multi-chip module according to one of the preceding claims, characterized in that the internal circuit board has a wiring layer with a plurality of wiring layers ( 2 , 3 , 4 ), each of which is separated from one another by a layer ( 5 , 6 ) made of insulating material The insulating layer ( 5 , 6 ) is provided with cutouts ( 7 ) for connecting certain lines of the wiring layers ( 2 , 3 , 4 ).