HIGH POWER AND HIGH FREQUENCY PLASTIC PRE-MOLDED CAVITY PACKAGE
A cavity package is set forth along with a method of manufacturing thereof. According to one embodiment, the method comprises attaching a metal heat sink to a leadframe using an intermediate structure that is thermally conductive and electrically insulating; molding a plastic body around the heat sink and exposed leads of the leadframe to form a cavity, with partially and selectively exposed lead top surfaces, heat sink top surface, and heat sink bottom surface; attaching a semiconductor device die within cavity on to the exposed top surface of the heat sink using a thermal conductive material; wire bonding respective wire bond pads of the semiconductor device die to the exposed lead top surfaces and to the heat sink for grounding; and attaching a lid to the plastic molded body to protect the wire bonded device within cavity.
This is a divisional of U.S. patent application Ser. No. 14/966,636, filed Dec. 11, 2015, the contents of which are hereby incorporated by reference.
FIELD OF INVENTIONThe present invention relates generally to integrated circuits, and more particularly in one aspect to a high power, high frequency plastic pre-molded cavity package and in another aspect to a hermetically sealed high power, high frequency plastic pre-molded cavity package.
BACKGROUNDCeramic cavity and plastic over-mold with embedded heat sink packages are known in the art for housing high power, high frequency devices such as RF power transistors. Ceramic cavity packages are designed with a cavity (containing air or nitrogen) for housing a semiconductor die (IC), whereas plastic-molded packages contain minimal air in the package. The basic structure of such packages is a die attach pad on which the semiconductor die is mounted, a thermally conductive heat sink or heat spreader for dissipating heat from the die, metal leads for signal input/output with the semiconductor die, and a cap or lid. In cavity packages, the lid is metal whereas in over-mold plastic packages the entire package is over-molded in plastic, but with a portion of the heat sink exposed.
Prior art ceramic cavity packages are expensive in terms of the material used, exhibit poor thermal performance due to the use of ceramic-copper-based laminate material for the heat sink, and are not scalable for mass production.
One reason for the development of plastic over-molded with embedded heat sink packages was to provide improved thermal performance over ceramic cavity packages. Plastic packages use a copper heat sink on which the IC is mounted instead of the copper-based laminate material used in prior art cavity packages, such that when the die is mounted on the copper heat spreader, there is a reduction in the thermal resistance as compared to when the die is mounted on air cavity packages having a ceramic-copper-based laminate heat sink.
Also, prior art ceramic cavity packages are typically assembled individually, whereas plastic packages are assembled in a leadframe configuration as a group. This makes the assembly process faster and results in less manual handling.
However, plastic over-mold with embedded heat sink packages suffer from the disadvantage of not providing a cavity, as well as lacking a good thermal path from the leadframe to the heat sink because the top surface of the heat sink does not in direct contact with the bottom surface of the leads of the leadframe.
SUMMARYA cavity package and method of fabrication are set forth for ameliorating at least some of the disadvantages of prior art ceramic and plastic over-mold packages. According to a first embodiment of the present invention, a metal heat sink is attached to a leadframe via an intermediate structure that is thermally conductive but electrically insulating. A plastic body is molded onto the integrated heat sink and leadframe to form a cavity, with partially and selectively exposed lead surfaces as well as top and bottom surfaces of the heat sink. The die is attached to the exposed top surface of the heat sink within the cavity and wire bonded to the lead surfaces. Finally, a lid is attached to the plastic molded body to seal the cavity.
In accordance with another aspect of the first embodiment, there is provided a method comprising attaching a metal heat sink to a leadframe using an intermediate structure that is thermally conductive and electrically insulating; molding a plastic body around the heat sink and exposed leads of the leadframe to form a cavity, with partially and selectively exposed lead top surfaces, heat sink top surface, and heat sink bottom surface; attaching a semiconductor device die within cavity on to the exposed top surface of the heat sink using a thermal conductive material; wire bonding respective wire bond pads of the semiconductor device die to the exposed lead top surfaces and to the heat sink for grounding; and attaching a lid to the plastic molded body to protect the wire bonded device within cavity.
According to a second embodiment, a metal heat sink is attached to a leadframe via a first intermediate ring-type structure that is thermally conductive but electrically insulating. A further thermally conductive and electrically insulating ring-type intermediate structure is attached to the top of the leadframe. In one embodiment, each ring-type structure preferably comprises a “sandwich” of thin metal portions bonded to top and bottom surfaces of a ceramic middle portion. Opposite sides of the top thin metal portion of the first ring-type structure are bonded to respective bottom surfaces of the metal leads, while the bottom surface of the first ring-type structure is bonded to the heat sink. Opposite sides of the bottom thin metal portion of the further ring-type structure are bonded to respective top surfaces of the metal leads. A plastic body is molded onto the integrated heat sink and leadframe to form a cavity, with partially and selectively exposed portions of the metal leads as well as top and bottom surfaces of the heat sink and the top thin metal portion of the further ring-type intermediate structure. The die is attached to the exposed top surface of the heat sink within the cavity and wire bonded to the lead surfaces. Finally, a metal lid is attached to the plastic molded body to seal the cavity.
In accordance with a further aspect of the second embodiment, there is provided a method comprising attaching a metal heat sink to a leadframe using an intermediate structure that is thermally conductive and electrically insulating; molding a plastic body around the heat sink and exposed leads of the leadframe to form a cavity, with partially and selectively exposed lead top surfaces, heat sink top surface, and heat sink bottom surface; attaching a semiconductor device die within cavity on to the exposed top surface of the heat sink using a thermal conductive material; wire bonding respective wire bond pads of the semiconductor device die to the exposed lead top surfaces and to the heat sink for grounding; and attaching a metal lid to the plastic molded body to protect the wire bonded device within cavity.
In accordance with an additional aspect the metal heat sink comprises copper (Cu) or other metal alloy.
In a variant of the first embodiment, the intermediate structure is ceramic.
In accordance with an additional aspect, the leadframe preferably includes a rectangular outer frame.
In accordance with an additional aspect of the first embodiment, the thermal conductive material comprises one of either silver epoxy or solder.
In accordance with an additional aspect of the first embodiment, the lid is attached to the plastic molded body by means of epoxy.
In accordance with an additional aspect of the first embodiment, the lid is made of liquid crystal polymer, epoxy mold compound, metal or other suitable material.
In accordance with a further aspect of the first embodiment, a cavity package is provided comprising a plastic body surrounding and partially exposing an integrated heat sink and leads of a leadframe, and a lid.
In accordance with an additional aspect of the first embodiment, the cavity package includes a pair of leads extending from opposite sides of the leadframe.
In accordance with an additional aspect of the first embodiment, the cavity package includes at least two leads extending from each side of the leadframe.
According to a further aspect of the second embodiment, each intermediate “sandwich” structure comprises ceramic with Direct Bond Copper (DBC) in which a thin layer of copper is bonded to the top and bottom surfaces of the ceramic middle portion. The thin layers of copper are electrically isolated from each other by the intermediate ceramic portion. The shape of the ceramic portion as well as the pattern of the thin layers of copper can be designed and fabricated in accordance with methodologies known to persons of skill in the art. The bottom thin layer of copper of the first intermediate structure is bonded to the top side of the heat sink (e.g. using Ag epoxy or soldering). In one embodiment, the pattern of the bottom thin layer of copper is a complete ring pattern. Since the top thin layer of copper is designed to bond to the bottom side of the two leads of the package and since the two leads are eventually electrically isolated after singulation, the pattern of the top thin layer of copper of the first intermediate structure can be a broken ring shape (e.g. a “[ ]” shape, for a two-lead package design).
In accordance with an additional aspect of the second embodiment, the thermal conductive material of both the first and further intermediate structures comprises one of either silver epoxy or solder.
In accordance with an additional aspect of the second embodiment, the lid is attached to the metal ring portion of the further intermediate structure on top of the metal leads, for example via solder.
In accordance with an additional aspect of the second embodiment, the lid may be made of copper, stainless steel plated with nickel and/or Sn to facilitate the soldering process.
The cavity package according to the present invention is small and lightweight, with good thermal and electrical performance that makes it suitable for industrial high power and high frequency applications. The cavity package according to the present invention is more cost effective than ceramic cavity packages because it uses more common materials such as copper and plastic epoxy molding compound, and can be manufactured in high volume due to its multiple leadframe construction.
The cavity package according to the present invention is suitable for high frequency and high power applications (e.g. RF switching transistors) by providing an integrated heat sink for dissipating heat generated by the die and wires through the leadframe and intermediate structure. High frequency operation is made possible due to the air cavity in which the die and bonded wires are disposed (air having the best dielectric constant for high speed).
Features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention; and, wherein:
Reference will now be made to the exemplary embodiments illustrated, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended.
DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTSBefore the present invention is disclosed and described, it is to be understood that this invention is not limited to the particular structures, process steps, or materials disclosed herein, but is extended to equivalents thereof as would be recognized by those ordinarily skilled in the relevant arts. It should also be understood that terminology employed herein is used for the purpose of describing particular embodiments only and is not intended to be limiting.
A high power, high frequency plastic pre-molded cavity package 100 is shown in
With reference to
Construction of the cavity package begins at step 200 (
At step 210, plastic body 110 is molded around the integrated heat sink 120 and leads 130 of leadframe 300 to form a cavity 400, with partially and selectively exposed lead top surface 410, heat sink top surface 420, and heat sink bottom surface 430, as shown in
At step 220, a semiconductor device die 500 (i.e. the IC) is placed within cavity 400 on to exposed top surface 420 of the heat sink and attached to the using a thermal conductive material, such as silver epoxy, solder, etc., as shown in
Respective wire bond pads of semiconductor device die 500 are then wire bonded 600 to the exposed lead top surfaces 410 and to the heat sink 120 for grounding, at step 230, as shown in
Finally, at step 240, lid 140 is attached 11190 is attached to the plastic molded body 110 by means of epoxy to protect the wire bonded device within cavity 400. The lid may be made of liquid crystal polymer, epoxy mold compound, metal or other suitable material.
As discussed above, in practice a matrix of cavity packages is fabricated (not shown) such that after the lid 140 has been attached, the matrix is singulated (e.g. using saw singulation) to create packages, such as the package shown in
A high power, high frequency plastic pre-molded cavity package 100 is shown in
With reference to
Construction of the cavity package begins at step 200′ (
As illustrated in
A further thermally conductive and electrically insulating intermediate ring-type structure 320′ is then attached (step 205′) to the top surface of leads 130′ of leadframe 300′. The further intermediate structure 320′ is of similar “sandwich” construction as the first structure 310′. The bottom thin layer of copper is attached to the metal leads 310′ such that the pattern can be either a broken ring (i.e. “[ ]”) or a parallel line pair, whereas the top thin layer of the copper forms a complete ring pattern onto which a lid is attached (see
At step 210′, plastic body 110′ is molded around the integrated heat sink 120′ and leads 130′ of leadframe 300′ to form a cavity 400′, with partially and selectively exposed lead top surface 410′, heat sink top surface 420′, heat sink bottom surface 430′, and top surface of ring-type structure 320′, as shown in
At step 220′, a semiconductor device die 500′ (i.e. the IC) is placed within cavity 400′ on to exposed top surface 420′ of the heat sink and attached to the using a thermal conductive material, such as silver epoxy, solder, etc., as shown in
Respective wire bond pads of semiconductor device die 500′ are then wire bonded 600′ to the exposed lead top surfaces 410′ and to the heat sink 120′ for grounding, at step 230′, as shown in
Finally, at step 240′, metal lid 140′ is attached to the plastic molded body 110′ by means of soldering to the top exposed ring on the further (i.e. top) intermediate structure 320′. The metal lid 140′ is stronger than a plastic lid, is cheaper than ceramic, and can be fabricated from a one of many metals such as copper or stainless steel with plated nickel or tin.
As discussed above, in practice a matrix of cavity packages is fabricated (not shown) such that after the lid 140′ has been attached, the matrix is singulated (e.g. using saw singulation) to create packages, such as the package shown in
At step 195, a leadframe 300, as depicted in
At step 198, the metal heat sink 120 (e.g. Cu or other metal alloy) is attached to the bottom of the leadframe 300 using an electrically insulative interface (e.g. non-conductive epoxy, double sided adhesive tape, etc. . . . )
Following the heat sink attachment step 198, the remaining molding, die attach, wire bonding and lid attachment steps 210-240 are performed, as discussed above with reference to
The many features and advantages of the invention are apparent from the detailed specification and, thus, it is intended by the appended claims to cover all such features and advantages of the invention that fall within the true spirit and scope of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation illustrated and described, and accordingly all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.
Claims
1. A method of manufacturing a cavity package comprising:
- i) attaching a metal heat sink to a leadframe using an intermediate structure that is thermally conductive and electrically insulating;
- ii) molding a plastic body around the heat sink and exposed leads of the leadframe to form a cavity, with partially and selectively exposed lead top surfaces, heat sink top surface, and heat sink bottom surface;
- iii) attaching a semiconductor device die within cavity on to the exposed top surface of the heat sink using a thermal conductive material;
- iv) wire bonding respective wire bond pads of the semiconductor device die to the exposed lead top surfaces and to the heat sink for grounding; and
- v) attaching a lid to the plastic molded body to protect the wire bonded device within cavity.
2. A cavity package manufactured in accordance with the method of claim 1, comprising a plastic body surrounding and partially exposing an integrated heat sink and leads of a leadframe, and a lid.
3. A method of manufacturing a cavity package comprising:
- i) bending lead tips of a leadframe to form respective steps;
- ii) attaching a metal heat sink to the respective leadframe using an electrically insulative interface;
- iii) molding a plastic body around the heat sink and exposed leads of the leadframe to form a cavity, with partially and selectively exposed lead top surfaces, heat sink top surface, and heat sink bottom surface;
- iv) attaching a semiconductor device die within cavity on to the exposed top surface of the heat sink using a thermal conductive material;
- v) wire bonding respective wire bond pads of the semiconductor device die to the exposed lead top surfaces and to the heat sink for grounding; and
- vi) attaching a lid to the plastic molded body to protect the wire bonded device within cavity.
Type: Application
Filed: Jan 8, 2018
Publication Date: May 3, 2018
Inventors: Zhang Xiao PING (Ningdu), Sin Chi WAI (Kowloon)
Application Number: 15/864,481