1. Technical Field
This disclosure relates to RF power transistors, and more particularly to power transistor packages.
2. Discussion of Related Art
Conventional high-power RF power transistor packages use metal flanges that generally protrude from multiple sides of the device. Such flanges provide source electrical interconnects and a means for affixing the device to a heat sink. The flanged connections can be beneficial for high-frequency applications and usually include bolt holes outwardly positioned from the package for clamping the device to the heat sink.
An example of a prior-art RF power transistor package 100 having flanges 105 and 110 is show in
However, the conventional art is cost-disadvantageous due to extra materials used in the construction of the package. Prior art packages are also deficient in other areas such as manufacturing simplicity. Moreover, the prior art approach to connecting source interconnects to the heat sink does not benefit from preferential deformation of the lid when mounting the package. Accordingly, a need remains for a lower-cost high-power RF power transistor package using less material, better connectivity features, and providing for preferential deformation of the package when affixing the device to the heat sink.
In an example embodiment of the invention, an RF power transistor package is provided. The RF package can include, for example, a substrate mountable on a base plate, a non-conductive cover overlying the substrate, and quasi-serpentine stepped source leads attached to an upper surface of the substrate and extending from at least one of a pair of opposite sides of the upper surface of the substrate to tapered lower surfaces of the cover. The non-conductive cover can include a recess configured to receive the substrate. The recess forms a stress distribution surface area to engage and press outer edge portions of opposite sides of the substrate against the base plate.
One or more tapered lower surfaces of the cover extend from the recess toward outer edge portions of the cover. The tapered lower surfaces of the cover engage with and press against the stepped source leads when securing the RF package to the base plate or heat sink. Mounting the package to base plate or heat sink can involve the use of one or more fasteners or bolts inserted into bolt holes and through corresponding openings in the stepped source leads. The fasteners or bolts are received by mounting holes in the base plate or heat sink.
The cover includes structural features to improve preferential deformation when a mounting force is applied. For instance, the recess in the cover includes one or more notches at outer edges thereof, to provide stress concentration outwardly toward edges of the cover. The cover can also include a cavity disposed within the cover to receive one or more dies, one or more conductors, and at least portions of one or more gate leads, one or more drain leads, and the one or more stepped source leads. The cover can include sections having different thicknesses to provide rigidity to some portions of the cover while evenly distributing stress of the cover during preferential deformation thereof.
The foregoing and other features and advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention that proceeds with reference to the accompanying drawings.
The RF power transistor package 200 includes a substrate 220 mountable on a base plate or heat sink (not shown). The substrate 220 is typically made of ceramic having high yield stress properties, although any suitable material can be used. One or more silicon dies 405 forming the circuitry of the device can be disposed on and/or affixed to the upper surface of the substrate 220.
A non-conductive cover 205 is structured to overlay and protect the substrate 220 and other components of the package. The cover 205, sometimes referred to as a “lid” can be unitary, resilient, generally rectangular with rounded corner edges 230, and overlying the substrate 220, silicon dies 405, wire bonds 415, stepped source leads 305, and portions of leads 210 and 215. The cover 205 is made of a material selected to provide high electrical insulation with low dielectric loss.
The cover material preferably has a high resistance to creep to avoid non-preferential deformations caused by numerous heat cycles. Materials such as Ultem® UC1200 Polyetherimide, Lexan® 920A Polycarbonate, Makrolon® 1804 Polycarbonate, or Ultem® 2300 can be used as the base material for the cover 205. Preferably, Ultem® 2300 is used due to its yield strength, creep resistance, and performance in an injection molding application. Injection molding applications are the preferred method for producing the cover 205 in large quantities.
The cover 205 includes a recess 222 to receive the substrate 220. The recess 222 forms a stress distribution surface area 410 to engage and press outer edge portions 410 of opposite sides of the substrate 220 against the base plate or heat sink. The recess 222 can also receive at least portions of a lead frame and/or leads associated with the RF package 200.
One or more stepped source leads 305 extend from at least one of a pair of opposite sides of an upper surface of the substrate 220 to the lower surfaces of the cover 205. Each source lead 305 is attached to the top of the ceramic substrate 220 using bolts, rivets, adhesive, or other suitable attaching means, and is electrically coupled to the dies 405. The stepped source leads 305 can be bent or folded in a quasi-serpentine fashion to form an electrical connection from the top of the substrate 220 to the base plate or heat sink, as will be further described below.
Gate leads 215 and drain leads 210 are attached to the top surface of the ceramic substrate 220 using the same or similar attaching means. The gate and drain leads are electrically coupled to the dies 405, and protrude in opposite directions from the other two sides of the substrate 220. The stepped source leads, gate leads and drain leads can be electrically coupled to the dies 405 using one or more electrical conductors, for example, such as wire bonds or “jumper” wires 415 illustrated in
Mounting or bolt holes 225 are arranged in the cover 205 and are aligned with corresponding openings 310 in the stepped source leads 305. Although the openings 310 are illustrated as elongated moon-shaped openings, other types of openings are contemplated such as circular openings that substantially match those of holes 225, among other possibilities. The mounting or bolt holes 225 are used for securing the RF package 200 including the substrate 220 and the stepped source leads 305 directly to the base plate or heat sink. The mounting or bolt holes 225 can be arranged in a pattern that matches the mounting pattern of preexisting RF power transistor packages or in entirely new mounting arrangements.
The stepped source leads 305 are disposed entirely beneath the non-conductive cover 205 and need not extend beyond the edges of the cover. In other words, the RF package includes flangeless source connections to the base plate or heat sink, providing an electrical connection from the top side or active portion of the substrate 220 to the underside or mounting surface of the RF package 200, entirely within and/or beneath the geometry of the cover 205.
One or more tapered lower surfaces 725 extend from the recess 222 toward outer edge portions 720 of the cover 205. The tapered lower surfaces 725 provide an interface between the RF package and the base plate or heat sink, which results in consistent and preferential lid deformation and/or creep resistance due to plastic relaxation of the lid. The one or more stepped source leads 305 extend from at least one of a pair of opposite sides of an upper surface of the substrate 220 to the tapered lower surfaces 725 of the cover 205. The stepped source leads 305 can extend partially toward the outer edge portions 720 of the cover 205 as illustrated, or in an alternative embodiment, the stepped source leads 305 can extend entirely to the outer edge portions 720 of the cover 205.
Each of the stepped source leads 305 includes a first horizontal section 715, a slanted section 710, and a second horizontal section 705. The first section 715 is coupled to the upper surface of the substrate 220, which defines a horizontal dimension of the first section 715. The slanted section 710 extends in a sloped direction from the first section at an angle θ1 relative to the horizontal dimension of the first section. The angle θ1 is preferably 100 degrees or thereabout, but in some embodiments, the angle θ1 can be any suitable angle between 90 and 170 degrees. A second horizontal section 705 extends from the slanted section at an angle θ2 relative to the slanted direction of the slanted section. The angle θ2 is preferably 100 degrees or thereabout, but in some embodiments, the angle θ2 can be any suitable angle between 90 and 170 degrees.
The first horizontal section 715, slanted section 710, and second horizontal section 705 form a contiguous stepped source lead 305 located beneath the cover 205. As mentioned above, the stepped source leads 305 can be bent or folded in a quasi-serpentine embodiment. The transitions from one section of a stepped source lead 305 to another is defined by angles θ1 and θ2, which can be rounded or sharp. The tapered lower surfaces 725 of the cover 205 provide consistent and repeatable application of mounting force on the stepped source leads 305 to ensure high surface contact area between the source leads and the base plate or heat sink 605.
In addition, consistent contact pressure is applied by the tapered lower surfaces 725 to the source leads 305 to also enhance contact and to prevent creep resistance that could otherwise be caused by plastic relaxation of the cover. More specifically, the tapered lower surfaces 725 of the cover 205 are structured to engage with and press against the second horizontal section 705 of the one or more stepped source leads 305, even over the course of multiple heating and/or usage cycles.
Furthermore, one or more notches 505 in the cover 205 are disposed at outer edges of the recess 222. The notches 505 provide stress concentration outwardly toward edges of the cover 205. The notches 505 also provide preferential deformation of the cover 205 about the first horizontal section 715 and slanted section 710 of the stepped source leads 305, particularly when securing the RF package 200 to the base plate or heat sink 605 using, for example, one or more fasteners or bolts 750.
A cavity 745 is disposed within the cover 205 to receive the one or more dies 405, one or more conductors such as the wire bonds 415, and at least portions of the one or more gate leads 215, drain leads 210, and stepped source leads 305. The cavity 745 includes a first section 730 having a first thickness to provide rigidity to the central portion of the cover 205, one or more additional sections 735 having a second thickness less than the first thickness, and a curved section 740 connecting the first section to the one or more additional sections.
The one or more additional sections 735 and the curved section 740 are configured to evenly distribute stress of the cover 205 during preferential deformation thereof when securing the one or more stepped source leads 305 and the substrate 220 to the base plate 605 using, for example, the one or more fasteners or bolts 750. Stress is further distributed on the substrate 220 by the lid to substrate bearing area 410, which makes contact with and presses against the outer edge portions 410 of opposite sides of the substrate 220, which in turn presses the substrate 220 and stepped source leads 350 against the base plate or heat sink 605.
Fasteners or bolts 750 can be inserted through holes 225 and openings 310 into mounting holes 755 of the base plate or heat sink 605, which securely mounts the RF package 200, including the cover 205, substrate 220, leads, and other associated components of the RF package to the base plate or heat sink 605. While one section of the RF package is shown along lines VII-VII in
Having illustrated and described the principles of our invention in various embodiments thereof, it should be apparent that the invention can be modified in arrangement, detail and application without departing from such principles. While some embodiments described herein are especially useful in packaging RF power devices, embodiments of the invention can be configured for use with other types of devices such as lower frequency devices.
For instance, the terminology “gate,” “source” and “drain” leads pertains to MOSFET type devices. It is contemplated that embodiments of the invention can also be used with bipolar type devices and IGBT devices. In the case of bipolar devices, gate corresponds to base, source corresponds to emitter and drain corresponds to collector. In the case of an IGBT device, gate remains gate, source corresponds to emitter and drain corresponds to collector. The terms gate, source and drain will be used throughout but are meant to include base-emitter-collector and gate-emitter-collector leads.
I claim all modification and variations coming within the spirit and scope of the following claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/261,337, filed Nov. 15, 2009, herein incorporated by reference.
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