WO2012038121A1

WO2012038121A1 - Flip-chip assembly having a cooling element and method for producing a flip-chip assembly

Info

Publication number: WO2012038121A1
Application number: PCT/EP2011/062879
Authority: WO
Inventors: Volker Weeber
Original assignee: Robert Bosch Gmbh
Priority date: 2010-09-23
Filing date: 2011-07-27
Publication date: 2012-03-29
Also published as: DE102010041261A1

Abstract

In a flip chip assembly (10, 20) comprising a flip chip (11, 21) having contact surfaces (12) on an upper face (13) and a cooling element (15, 22) arranged on a lower face (14, 24) of the flip chip, the cooling element (15, 22) consists of a material which has a similar thermal expansion coefficient to that of the material of the flip chip (11, 21). Preferred materials are ceramics and materials based on carbon, in particular graphite or aluminum comprising carbon fibers. The cooling element (22) can be designed as an expansion element (25) and can be connected to an external heat sink (26) by means of a resilient heat-conducting medium (27).

Description

description

title

Flip-chip arrangement with a cooling element and method for producing a flip-chip arrangement

State of the art

Semiconductor devices made of silicon or similar semiconductor materials

Usually packaged in housing, which are then soldered to circuit board. For heat transport often copper sheets are integrated into the housing, on which the semiconductors are glued. In some cases, the semiconductor devices are also glued as unpackaged chips, "bare die", with the back on ceramic circuit boards and then bonded on the active front to the circuit carrier. There is also the so-called flip-chip technology, in which the chips with the active side directly on the

Circuit board to be glued or soldered. Compared to the usual packaging, the chip is then reversed, ie with the active top side down, on the

Circuit carriers. Without additional measures, flip chips may only have a limited

Generate heat loss because the heat can not be dissipated area, but only on the connection points. If flip-chips produce greater power dissipation then they must be cooled across the backside. For this purpose, usually after soldering metallic cooling elements are glued or pressed onto the back, the adhesive or nip must be as small as possible to keep the thermal resistance as small as possible. The cooling elements are often connected to a housing that covers the entire

Circuit carrier encloses. Cooling elements according to the prior art usually have a higher thermal expansion coefficient than the flip-chip. If the flip-chip is adhesively bonded to the cooling element, then the system will become attached

Temperature changes exposed to mechanical stress, either the

Cooling element bonding, which can damage the solder connection to the circuit carrier or the flip-chip itself. As a remedy, the flip-chip can be connected to the cooling element instead of via a bond via a liquid or permanently elastic heat-conducting medium. In this case, the cooling element must be pressed by suitable means on the flip-chip. These funds are usually relatively expensive. In addition, there is a risk that the layer thickness of liquid or permanently elastic Wärmeleitmediums over the life is not constant or can be kept so small only with elaborate measures that the thermal resistance of this layer is sufficiently small. US Pat. No. 5,610,442 discloses in a first variant a conventional chip arrangement in which the chip rests on a circuit carrier with the underside and is connected to the circuit carrier by means of bonding wires on the top side of the chip. On a central partial surface of the top of the chip, a planar substrate is glued, on which in turn an external heat sink is arranged. The planar substrate comprises a rigid material such as silicon, ceramic or metal to serve automated handling of the chip. If the coefficient of thermal expansion of the planar material is different than that of the active die, a suitable adhesive of appropriate thickness may be used to avoid shear stresses due to differential thermal expansion. The chip, the bonding wires and the side surfaces of the planar substrate are encapsulated.

US Pat. No. 5,610,442 discloses, in a second variant, a flip-chip arrangement in which the chip is soldered with the top side onto a circuit carrier. On an central partial surface of the underside of the chip, an external heat sink is arranged. The flip-chip variant expressly does not use the planar substrate of the conventional variant. The chip and the solder connection are encapsulated.

On the other hand, the flip-chip arrangement according to the invention has the advantage that a cooling element can be bonded to the flip-chip with a very thin adhesive layer, without mechanical stresses acting on the flip-chip as a result of this bonding in the event of temperature changes. In one embodiment of the invention, a cooling element has only a relatively small geometric extent and is used only as a spreading element to the

Cross-sectional area to increase in heat flow direction. It is advantageous in a larger cross-sectional area in the further course of the heat path, the layer thickness of a

subsequent liquid or permanently elastic coupling layer to parent Heat sinks much less critical, ie, the heat resistance of such a layer remains sufficiently small even with a larger layer thickness due to the larger cross-section.

Brief description of the drawings

Embodiments of the invention will be explained with reference to the drawings, in which Fig. 1 is a schematic representation of a flip-chip arrangement according to a

Embodiment of the present invention shows;

Fig. 2 is a schematic representation of a flip-chip arrangement according to another

Embodiment of the present invention shows; and

3 is a flowchart of the method according to an embodiment of the present invention

Invention shows.

Embodiments of the invention

Fig. 1 shows a flip-chip assembly 10 with a flip-chip 1 1 with contact surfaces 12 on an upper side 13 and on a lower side 14 of the flip-chip 1 1 arranged cooling element 15 according to an embodiment of the present invention. The flip Chip 1 1 is by means of solder balls 16 on contact surfaces 12 with a circuit carrier 17,

For example, a printed circuit board 18, connected. The cooling element 15 is connected to the flip-chip 1 1 via an adhesive layer 19, which extends over the entire underside 14 of the flip-chip 11. The cooling element 15 covers the entire bottom 14 of the flip-chip and extends laterally beyond the bottom 14 of the flip-chip 1 1 addition. The cooling element 15 is made of a material which has a similar thermal expansion coefficient as the material of the flip-chip 1 1. The cooling element 15 is made of graphite in this example. Alternative materials include ceramics and other materials

Carbon base, in particular the material aluminum with carbon fibers. The flip-chip assembly 10 according to the invention has the advantage that the cooling element 15 can be glued to the flip-chip 1 1 with a very thin adhesive layer 19, without mechanical stresses acting on the flip chip 1 1 by this bond with temperature changes. Fig. 2 shows a flip-chip assembly 20 according to another embodiment of the present invention. Flip-chip 21 is connected in the same way as flip-chip 1 1 of FIG. 1 to the circuit board 18. Again, a cooling element 22 is connected to the flip-chip 21 via an adhesive layer 23, which extends over the entire underside 24 of the flip-chip 21. The cooling element 22 covers the entire underside 24 of the flip-chip and extends laterally beyond the bottom 24 of the flip-chip 21. However, the cooling element 22 is now designed as a spreading element 25, which forms a heat connection to a heat sink 26. The cooling element 22 is connected to the heat sink 26 by means of an elastic heat conducting medium in the heat conducting layer 27. The cooling element 22 is made of a material which has a similar thermal expansion coefficient as the material of the flip-chip 21. The cooling element 15 is made of graphite in this example.

Alternative materials are ceramics and other carbon-based materials,

in particular the material aluminum with carbon fibers. The cooling element 22 has only a relatively small geometric extent and is used only as a spreading element 25 in order to increase the cross-sectional area in the heat flow direction. The area of the heat-conducting layer 27 is much larger than the area of the adhesive layer 23 or the

Bottom 24 of the flip-chip 21, therefore, the heat resistance of the heat-conducting layer 27 remains sufficiently small even with a larger layer thickness and good heat conduction of the heat from flip-chip 21 to the heat sink 26 is achieved. The heat sink 26 may be an external heat sink, for example a housing part.

3 shows in flowchart 30 the method for producing a flip-chip arrangement with a flip-chip having contact surfaces on an upper side and a cooling element arranged on the underside of the flip-chip according to an embodiment of the present invention. The process begins with the process step

a) Positioning the flip-chip so that the bottom is freely accessible. Then follows process step

b) arranging the cooling element on the underside, wherein the cooling element consists of a material which has a similar coefficient of thermal expansion as the material of the flip-chip.

Advantageously, the cooling element is glued to the underside of the flip-chip by means of adhesive.

The cooling element preferably comprises a material of ceramic and materials

Carbon base, in particular the material graphite or the material aluminum with Carbon fibers, on.

In a further embodiment of the invention, a heat sink is arranged on the cooling element, wherein advantageously the cooling element is connected to the heat sink by means of an elastic heat conduction medium.

Claims

claims

Flip-chip arrangement (10, 20) with a flip-chip (1 1, 21) with contact surfaces (12) on an upper side (13) and one on the underside (14, 24) of the flip-chip

arranged cooling element (15, 22), characterized in that the cooling element (15, 22) consists of a material which has a similar

Thermal expansion coefficient as the material of the flip-chip (1 1, 21).

Flip-chip arrangement according to claim 1, characterized in that the cooling element (15, 22) covers the entire underside (14, 24) of the flip-chip (1 1, 21).

Flip-chip arrangement according to claim 1 or 2, characterized in that the cooling element (15, 22) laterally beyond the flip-chip (1 1, 21) extends beyond.

Flip-chip arrangement according to one of the preceding claims, characterized

characterized in that the cooling element (15, 22) on the underside of the flip-chip (1 1, 21) by means of adhesive (14, 24) is glued.

Flip-chip arrangement according to one of the preceding claims, characterized

in that the cooling element (15, 22) comprises a material from the group of ceramics and materials based on carbon, in particular the material graphite or the material aluminum with carbon fibers.

Flip-chip arrangement according to one of the preceding claims, characterized

in that a cooling body (26) is arranged on the cooling element (22).

7. flip-chip arrangement according to claim 6, characterized in that the cooling element (15) with the heat sink (26) by means of an elastic heat conducting medium (27) is connected.

8. A method for producing a flip-chip arrangement with a flip-chip with

Contact surfaces on an upper side and on a lower side of the flip-chip arranged cooling element, with the method steps a) positioning the flip-chip so that the bottom is freely accessible; b) arranging the cooling element on the underside, wherein the cooling element consists of a material which has a similar coefficient of thermal expansion as the material of the flip-chip.

A method according to claim 8, characterized in that the cooling element is adhesively bonded to the underside of the flip-chip by means of adhesive.

10. The method according to claim 8 or 9, characterized in that the cooling element comprises a material from the group of ceramic and carbon-based materials, in particular the material graphite or the material aluminum with carbon fibers.

1 1. Method according to one of claims 8 to 10, characterized in that a cooling body is arranged on the cooling element.

12. The method according to any one of claims 8 to 1 1, characterized in that the

Cooling element is connected to the heat sink by means of an elastic heat conducting medium.