Patent Application
20190259689
A leadframe (LF) based package such as QFN (Quad Flat No-Lead) is a plastic encapsulated package which is popular in many applications needing efficient power dissipation where form factor, weight, and thermal and electrical performance are critical aspects. An exposed die paddle provides excellent thermal performance enhancements which are ideal for high frequency and high power applications and are especially suited for wireless and handheld portable applications such as cell phones.
The electronic package design involves a very complicated manufacturing process. One of the important aspects is thermal management. The main objective for thermal management is to cool down the integrated circuit (IC) chip/die that is secured by heat distribution from the IC die/chip to the ambient. This can be done in many ways. Previously, packages were not required to deal with cooling since they had low power input and temperature. The situation has changed with increasing performance and reduced area for cooling. Now, thermal management is a critical aspect of electronic package design.
U.S. Pat. No. 8,039,951 (Kanth et al), U.S. Pat. No. 9,214,416 (Furnival), and U.S. Pat. No. 7,557,432 (Tang et al) and U.S. Patent Applications 2015/0200149 (Zhao et al), 2008/0117957 (do et al), and 2016/0148890 (Khan et al) disclose various methods of heat dissipation in packages.
It is the primary objective of the present disclosure to provide heat dissipation for an integrated circuit package.
It is another objective of the present disclosure to provide multiple pathways of heat dissipation for an integrated circuit package.
It is a further objective of the present disclosure to provide multiple pathways of heat dissipation for an integrated circuit package by incorporating a re-routable clip in the package.
It is yet another objective of the present disclosure to provide a method of fabricating an integrated circuit package having multiple pathways of heat dissipation by incorporating a re-routable clip in the package.
In accordance with the objectives of the present disclosure, a method of fabricating an integrated circuit package having improved heat dissipation is achieved. A re-routable clip is provided having a central portion and a plurality of leads surrounding the central portion. A die is attached to an underside of the central portion of the re-routable clip. The die and the leads of the re-routable clip are attached to a substrate. The die and the leads are encapsulated with an encapsulation material wherein a top surface of the central portion of the re-routable clip is exposed to ambient air by the encapsulation material. The substrate is connected to a printed circuit board wherein thermal pathways are formed 1) from the die downward to the substrate to the printed circuit board and 2) from the die upward to the re-routable clip and then downward through the leads to the substrate and to the printed circuit board.
Also in accordance with the objectives of the present disclosure, an integrated circuit package is achieved. A metal re-routable clip is provided having a central portion and clips leads surrounding the central portion wherein the clip leads are attached to a substrate. A die having a top and a bottom surface is attached at the top surface to an underside of the central portion of the re-routable clip and attached at the bottom surface to the substrate. A mold compound encapsulates the die, the substrate, and the re-routable clip except for a top surface of the central portion of the re-routable clip which is exposed to ambient air by the mold compound. The integrated circuit package is attached to a printed circuit board wherein thermal pathways are formed 1) from the die downward to the substrate to the printed circuit board and 2) from the die upward to the re-routable clip and then downward through the clip leads to the substrate and to the printed circuit board.
The substrate can be: a leadframe, a quad flat no-lead (QFN) package, a dual flat no-lead (DFN) package, a ball grid array, a package-based chip stack, a package on package, a 3D integrated die stack, a multi-chip package, a land grid array, or a system in package.
In the accompanying drawings forming a material part of this description, there is shown:
In a leadframe based package, thermal design is closely related to the mounting possibilities on the board because of the direct contact between the printed circuit board (PCB) and the leads or die paddle of the QFN or Dual Flat No-Lead (DFN) package. Thermal design also influences the components near the package because of higher temperatures.
Thermal design historically has meant finding out which components in the system generate the most heat and coupling them to a heat sink. However, with power systems shrinking and becoming more cost-sensitive, heat sinks have become a less attractive option. New designs use the PCB as a heat sink. The conventional QFN, for example, is a leadframe package which has an integrated die paddle on the bottom that offers a low resistance path to conduct heat out of the device.
The present disclosure proposes to have a cavity down leadframe based package using a re-routable clip. As shown in
To further optimize thermal performance, not only does the heat need to conduct through the die paddle to the PCB, it also must effectively transfer into the surroundings and away from the device to the ambient air. Therefore, the present disclosure is critical to ensuring robust thermal heat dissipation.
Referring now more particularly to
Metal pillars or connectors 15 are built on the IC chip/die 14. Then the assembly is pick and placed on the die paddle of re-routable clip 22 and mounted on the clip 22 by the die attach material 16, as shown in
The metal pillars or connectors 15 attach the IC chip/die to the die paddle 11 of the leadframe 12. Leads 23 of the re-routable clip 22 are attached to leads 13 of the leadframe, as shown in
All components are encapsulated by a mold compound or other encapsulation material 20, as shown in bottom view in
The conductive feature 11 is coupled to a circuit board such as a PCB (not shown in
Mold compound 20 encapsulates the QFN package. Re-routable clip 22, IC die/chip 14, leadframe 12, conductive feature 11 and metal pillars 15 are completely embedded within mold compound 20. Re-routable clip 22 is partially encapsulated by mold compound 20. The top surface of re-routable clip 22 is not covered by mold compound 20 and it is co-planar with a top surface of the mold compound 20. One method is to over-mold; that is, the exposed part of re-routable clip will not be molded. Another method is to mold the entire package and then grind away the extra mold until the top surface of the re-routable clip is exposed to the ambient.
The key feature of the present disclosure is the dual pathway for heat dissipation from the IC chip/die downward to the die paddle to the underlying PCB and upward to the overlying re-routable clip from which the heat dissipates to the ambient or downward through the re-routable clip to the leadframe to the underlying PCB. These thermal paths are illustrated by the arrows 25 and 27 in
The dual pathway heat dissipation through re-routable clip can also be used in other types of packages, illustrated in
In
Thermal simulations were carried out to prove the heat dissipation effect of the re-routable clip of the present disclosure. Product A is a leadframe-based 32 flip-chip quad flat no lead (FC-QFN) package. The original package outline design (POD) is: die size=2.7×4.1×0.15 mm3 and the package size=5.0×7.0×0.577 mm3. The modified design uses the re-routable clip of the present disclosure. The package size of the modified package is 5.0×7.0×0.47 mm3. The total power dissipation is 1.843 W in four hot spot areas and the package is mounted on a 4-layer (4L) Joint Electron Device Engineering Council (JEDEC) standard board operating at an ambient temperature of 65° C. Table 1 illustrates the thermal simulation results.
As can be seen in Table 1, the junction temperature of Product A without the re-routable clip is 124.0° C. which is close to the maximum allowable junction temperature (i.e. 125° C.). The junction temperature of Product A with the re-routable clip is 117.6° C. The difference is 6.4° C. The thermal contours indicate that heating in the original Product A was localized or trapped inside the device. However, in the modified Product A, heat progressed towards the PCB and the top surface. This is due to the parallel combination of die paddle and re-routable clip.
A second thermal simulation was carried out from a customer in 2015. For the Product C design, the die size is 2.6×4.2×0.28 mm3 and the package size is 5.0×6.0×0.85 mm3. The total power dissipation is 2.63 W applied on 8 hot spot locations with a JEDEC 4L PCB. The simulation is operated at an ambient temperature of 65° C. and the maximum allowable junction temperature is 125° C. The original Product C showed a junction temperature of 140.9° C. The modified Product C with the re-routable clip had a junction temperature of 137.4° C. The difference is 4.6° C. The thermal contours indicated that the heat dissipation at the hot spot was concentrated on certain leads in the package without the re-routable clip. After applying the re-routable clip, the heat was evenly spread out and the hot spot was minimized.
A third thermal simulation was performed using Product C (34 FC-QFN) and another design Product B (30 FC-QFN). The two projects were mounted together on an application PCB. The die size of Product C was 2.6×4.2×0.28 mm3 and the die size of Product B was 2.6×5.04×0.28 mm3. The package size of Product C was 5.0×6.0×0.85 mm3 and the package size of Product B was 4.5×7.0×0.85 mm3. The total power dissipation on Product C was 2.63 W and on Product B, 2.28 W. The modified design used the re-routable clip of the present disclosure. The simulation was operated at an ambient temperature at 65° C. and the maximum allowable junction temperature was 125° C. Table 2 illustrates the simulation results for Product B and Product C.
The original design of Product B and Product C had junction temperatures of 103.2° C. and 114.3° C. while Product B and Product C with re-routable clip had junction temperatures of 99.1° C. and 108.2° C. All electronics are trending in the direction of higher power densities which require very uniform temperatures across the product while heating-up and cooling-down as quickly and as consistently as possible.
The temperature rise is illustrated by the curves in
The process of the present disclosure provides an integrated circuit package having multiple thermal pathways including: (1) from the die to an underlying substrate or frame and then to the underlying PCB and (2) from the die to the re-routable clip and then to the underlying substrate or frame and then to the underlying PCB and from the re-routable clip to the surrounding environment. With an extra heat dissipation path from the re-routable clip, the junction temperature of the package could be significantly reduced. Hence, the form factor and weight of the package could be further reduced or the power level could be much higher. In the process of the present disclosure, the leadframe package and the PCB do not need to be re-designed for thermal enhancement. The re-routable clip can be attached to any or all lead fingers of the leadframe if necessary to expand the heat dissipation path as much as possible. The lead fingers 12 can be used as input and output pins as well as heat dissipation paths.
Although the preferred embodiment of the present disclosure has been illustrated, and that form has been described in detail, it will be readily understood by those skilled in the art that various modifications may be made therein without departing from the spirit of the disclosure or from the scope of the appended claims.
