JP2005251969A - Multilayer composite lead frame and semiconductor package using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a composite lead frame in which a heat dissipation property and signal characteristics can be made to be highly functional, and its shape made to be small, thin, and short, and in which wiring can be freely disposed over the entire surface of an island for a semiconductor package obtained by mounting a semiconductor element on a multilayer composite lead frame in which leads are disposed on the island and its external peripheral part, an integrated metal material lead frame is employed as a main body, and an insulating sheet layer having a wiring part disposed therein is laminated on the island with an adhesive. <P>SOLUTION: The multilayer composite lead frame includes insulating sheets laminated sequentially up to a plurality of layers each having a plurality of wiring parts each having an input end and an output end both disposed on the surface of the wiring, and both ends are conducted via wiring. The wiring is disposed freely over the entire surface of the island, and the input end and the output end of at least each layer are exposed to the surface of the multilayer composite lead frame. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a multilayer composite lead frame used for a semiconductor package on which a semiconductor element is mounted and a semiconductor package using the same.

  A composite lead frame used for a semiconductor package on which a conventional semiconductor element is mounted is a lead frame made of a metal, for example, a copper material, in which an island on which a semiconductor element is mounted and a number of leads extending outward from the island are integrated. A device hole, which is a space hole for accommodating a semiconductor element, is provided in the center of the island, and a plurality of insulating sheets having a large number of wirings formed on the surface of the periphery of the device hole are laminated and pasted. It is made.

  FIG. 6 is a schematic view showing an example of a composite lead frame used in a semiconductor package on which a conventional semiconductor element is mounted and a semiconductor package on which the semiconductor element is mounted. 6A is a plan view of the lead frame partially enlarged, FIG. 6B is a plan view of the insulating sheet, and FIG. 6C is a side sectional view of the insulating sheet taken along line AA. 6 (d) is a side sectional view of AA of the composite lead frame in which the lead frame and the insulating sheet are bonded, and FIG. 6 (e) is an A- view of the semiconductor package in which the semiconductor element is mounted on the composite lead frame. It is a sectional side view of A. FIG. 6A is a plan view of a partial enlargement of the lead frame, in which an island (2) is formed in the center, a number of leads (3) are formed in the periphery thereof, and the lead (3) and the island are The input / output terminals of the semiconductor elements mounted on the board are connected by wire bonding. The insulating sheet (10) shown in FIG. 6 (b) has the same shape and size as the island (2) of the lead frame (1). In the insulating sheet, a space hole of the device hole (11) is formed in the central portion thereof, and the wiring portion (14) is arranged in the peripheral portion thereof. The wiring (13) can be freely arranged in the wiring part (14). The area of the wiring part (14) is smaller than the area of the island (2), and the area of the wiring part (14) decreases as the area of the device hole (11) increases. That is, if the area of the device hole (11) is increased, the wiring portion (14) is reduced, and therefore, the degree of freedom of wiring is lowered. On the other hand, the device hole (11) is indispensable for maintaining heat dissipation, and there is a problem that its area cannot be reduced below the bottom area of the semiconductor element. In recent years, there has been a demand for a solution to heat dissipation by increasing the functionality of semiconductor elements, and an increase in the degree of freedom of wiring has become necessary due to the increase in the number of pins of input / output terminals.

  FIG. 6 (d) shows a layer structure of a composite lead frame which is one of the methods for solving the increase in the degree of freedom of wiring. The insulating sheet (10) is bonded to each other. In the multi-layering, the insulating sheets (10) are sequentially laminated to form a multi-layer by the same method as described above. In the case of multiple layers, the area of the device hole is formed so that the upper insulating sheet is larger than the lower insulating sheet, and the device hole is widened toward the upper side at least at the side end of the device hole. Steps are provided. That is, in the multilayer structure, there is a problem that the area of the device hole is increased as it becomes higher (the multilayer structure), and the area of the wiring portion is reduced (see Patent Document 1).

FIG. 6E is a diagram in which a semiconductor element is mounted on the composite lead frame of FIG. The semiconductor element (30) is placed in the device hole, and is connected by wire bonding (33) from the input / output terminal of the semiconductor element (30) to the input end of the wiring (13) arranged on the insulating sheet (10). Then, the other lead end of the wiring (13) was further conducted by wire bonding (33) to the lead (3) of the lead frame (1). In addition, the wiring (13) of the insulating sheet has an input end portion on one side and an output end portion on the other side, and is connected to the end portion via the wiring. The input end portion and the output end portion serve as connection positions of the wire bonding (33).

The known literature is described below.
JP-A-5-183091

  As described above, in the composite lead frame, it is possible to increase the number of pins of the output terminal of the semiconductor element by stacking a large number of insulating sheets on which a large number of wirings are formed, and the amount of heat generated increases with the higher functionality of the semiconductor element. In response to the above, an improvement made possible by forming a device hole in the insulating sheet has been made. However, in the multilayer technology of the prior art, the area of the device hole increases as the area of the device hole increases to improve heat dissipation, and the area of the wiring area decreases. Accordingly, since the degree of freedom of wiring is decreasing, there is a problem that the number of layers is increased more than necessary, and there is a problem that wasteful manufacturing costs are applied.

  An object of the present invention is that a semiconductor package in which a semiconductor element is mounted on a composite lead frame can freely arrange wiring on the entire surface of an island, and it is possible to improve heat dissipation and signal characteristics, and to reduce the shape of the semiconductor package. It is to provide a composite lead frame. Furthermore, in the formation of a composite lead frame, it is an object to solve problems such as an unnecessarily multilayered structure and unnecessary manufacturing costs.

  The invention according to claim 1 of the present invention is an insulating sheet having a lead frame made of a metal material in which a large number of leads are arranged on an island and its outer periphery, and the island and the lead are integrated, and a wiring portion is arranged. In the multilayer composite lead frame formed by laminating a plurality of adhesives on the island, an insulating property in which a plurality of wiring portions are formed by connecting the input end portion and the output end portion disposed on the surface via the wiring. A multilayer composite lead frame in which a sheet is sequentially laminated up to a plurality of layers, wherein the wiring portion is freely arranged and formed on the entire surface of the island, and at least an input end portion and an output end portion of each layer are multilayer composite lead frames The multilayer composite lead frame is exposed on the surface of the multilayer composite lead frame.

  In the invention according to claim 2 of the present invention, the insulating sheet forms a wiring portion and a through hole and / or a device hole in which a plurality of wirings in which the incoming end portion and the outgoing end portion are conducted through the wiring are formed. 2. The multilayer composite lead frame according to claim 1, wherein

  In the invention according to claim 3 of the present invention, at least the lowermost insulating sheet is an insulating sheet in which no through hole and device hole are present and only a wiring portion is formed, and is adhered to the entire surface of the island. 3. The multilayer composite lead frame according to claim 1, wherein the multilayer lead frame is a multilayer composite lead frame.

  In the invention according to claim 4 of the present invention, the through hole and the device hole of the insulating sheet in which the wiring portion, the through hole, and the device hole are formed have the same shape on all the insulating sheets disposed above the insulating sheet. 4. The multilayer composite lead frame according to claim 1, wherein the multilayer composite lead frame is formed at the same position.

The invention according to claim 5 of the present invention is an insulating sheet layer in which a lead frame made of a metal material in which a large number of leads are arranged on an island and its outer periphery, and the island and the lead are integrated, and a wiring portion is arranged. 5. The multilayer composite lead frame insulating sheet according to claim 1, wherein a semiconductor element is mounted on a multilayer composite lead frame formed by laminating a plurality of adhesives on the island via an adhesive. On the semiconductor package, at least one semiconductor element is mounted via an insulating resin.

  The invention according to claim 6 of the present invention is the semiconductor package according to claim 5, wherein the semiconductor element is also mounted on an insulating sheet other than the uppermost insulating sheet.

  In the invention according to claim 7 of the present invention, the lead of the lead frame and the input / output terminal of the semiconductor element are connected and connected by wire bonding through the input and output ends of the wiring of the insulating sheet. 7. The semiconductor package according to claim 5, wherein the semiconductor package is a semiconductor package.

  In the composite lead frame on which the semiconductor element of the present invention is mounted, there is no device hole. Therefore, the wiring can be freely arranged on the entire surface of the island, so that the optimal layer position for the input / output signal line of the semiconductor element can be obtained. In this structure, the width and thickness can be arranged and formed in an optimal shape, and the degree of freedom of wiring is increased. Since there are no device holes to be formed to improve heat dissipation, it is possible to place and mount semiconductor elements on the entire surface of the island, so that more semiconductor elements can be mounted, and higher functionality and shape of the semiconductor package can be achieved. Short, small and thin. By the method of the present invention, there is an effect that problems such as unnecessary multilayering and useless manufacturing costs can be solved.

  The multilayer composite lead frame of the present invention will be described below based on one embodiment. FIG. 1 is an explanatory view of a semiconductor package using the multilayer composite lead frame of the present invention, and is a schematic side sectional view. As shown in FIG. 1, on the island (2) of the lead frame, the first insulating sheet (10) and the second insulating sheet (10) on the first insulating sheet (10) via an adhesive (20). It is the multilayer composite lead frame laminated | stacked one by one. In the first insulating sheet (10), a conductor layer in which only the wiring portion is formed is formed. The area is about the same as that of the island, and the wiring arrangement position and wiring shape, for example, the wiring width and wiring layer thickness can be freely selected to increase the degree of freedom of wiring. In the second insulating sheet (10), a wiring layer and a conductor layer having through holes (15) formed in two places are formed. The area of the wiring portion is slightly smaller than that of the first conductor layer, is an area excluding the positions of the input end portion and the output end portion of the first layer wiring, and two locations in the area. Other than the arrangement position of the through hole (15). Within the wiring portion, the wiring width and wiring layer thickness can be freely selected to increase the degree of freedom of wiring. The first and second wiring portions are independent wirings in each layer, and the wiring portions can be formed in accordance with manufacturing specifications independent in each layer. For example, the power supply signal line can be devised such as increasing the conductor thickness or increasing the signal line width. With a high-speed signal line, the wiring length can be made short and uniform, and the wiring can be miniaturized. In other words, it is classified according to the role of the input / output lines from the input / output terminals of the semiconductor device, divided into groups, and the lead frame leads via conductor layers such as low conductor resistance or uniform conductor layers such as characteristic impedance. Can be conducted.

Next, two semiconductor elements were mounted on the multilayer composite lead frame of the present invention. In conduction from the input / output terminal on the semiconductor element (30) to the lead (3) of the lead frame, the wire bonding (33) connects the input / output terminal to the second layer input terminal, and one layer from the input / output terminal. It connects with the entrance terminal of the eye by the wire bonding (33) through the through-hole. Next, a wire bonding (33) is connected from the second layer output terminal to the lead (3), and a wire bonding (33) is connected from the first layer output terminal to the lead (3). That is, a semiconductor package with good characteristics is completed by conducting from the input / output terminal on the semiconductor element (30) to the lead (3) of the lead frame via the first layer wiring or the second layer wiring.

  FIG. 2 is a schematic diagram for explaining input / output destinations of wiring on the insulating sheet of the present invention. In FIG. 2, the lead (3) is arranged on the outer peripheral portion, on the first insulating sheet having the same area as the island, on the first wiring portion (101) and on the second insulating sheet, A second-layer wiring portion (102) and a semiconductor element (30) are formed in a hierarchy thereon. Below, the path | route of the connection of each wiring is demonstrated. One input / output terminal (upper left in the figure) of the semiconductor element (30) is connected to the input terminal (131a) of the first layer wiring by wire bonding (33). The input terminal (131a) of the wiring is connected to the output terminal (131b) of the first layer wiring via the first layer wiring. The output terminal (131b) is connected to the lead (3) of the multilayer composite lead frame by wire bonding (33). Next, the input / output terminal (second from the upper left in the figure) is directly connected to the lead (3) by wire bonding (33). Next, the input / output terminal (third from the upper left in the figure) is connected to the input terminal (132a) of the second-layer wiring by wire bonding (33). The input terminal (132a) of the wiring is connected to the output terminal (132b) of the second-layer wiring via the second-layer wiring. The output terminal (132b) is connected to the lead (3) of the multilayer composite lead frame by wire bonding (33). That is, a signal from the input / output terminal of the semiconductor element is transmitted to the lead (3) of the multilayer composite lead frame via the wiring part (101) of the first insulating sheet, or directly ( 3) or three paths are formed to be transmitted to the lead (3) of the multilayer composite lead frame via the wiring portion (102) of the second insulating sheet. The degree of freedom is large.

  FIG. 3 is a partial sectional side view of an embodiment of a semiconductor package using the multilayer composite lead frame of the present invention. FIG. 3 shows a multilayer composite lead frame having a structure using a two-layer insulating sheet, and a wiring portion of the first insulating sheet (10) is formed on the entire surface of the island (2). This is a semiconductor package in which wirings (13) and device holes (11) are formed on a second insulating sheet (10), and two semiconductor elements (30) are mounted in parallel in the device holes. The signal from the input / output terminal of the semiconductor element (30) enters the input end of the first layer wiring (13) or the second layer wiring (13) by wire bonding (33), and through the wiring, The semiconductor package is transmitted to the leading end portion of the first layer wiring (13) or the second layer wiring (13), and is transmitted from the leading end portion to the lead (3) by the wire bonding (33).

  FIG. 4 is a partial sectional side view of an embodiment of a semiconductor package using the multilayer composite lead frame of the present invention. FIG. 4 shows a multilayer composite lead frame having a structure using a two-layer insulating sheet. A wiring portion of the first insulating sheet (10) is formed on the entire surface of the island (2), and two layers are formed on the entire surface. A wiring portion of the eye insulating sheet (10) is formed. This is a semiconductor package in which a wiring (13) is formed on a second insulating sheet (10), and a semiconductor element (30) is mounted on the wiring (13) via an adhesive made of an insulating resin. The signal from the input / output terminal of the semiconductor element (30) enters the input end of the first layer wiring (13) or the second layer wiring (13) by wire bonding (33), and through the wiring, The semiconductor package is transmitted to the leading end portion of the first layer wiring (13) or the second layer wiring (13), and is transmitted from the leading end portion to the lead (3) by the wire bonding (33).

FIG. 5 is a partial sectional side view of an embodiment of a semiconductor package using the multilayer composite lead frame of the present invention. FIG. 5 shows a multilayer composite lead frame having a structure using a two-layer insulating sheet, and a wiring portion of the first insulating sheet (10) is formed on the entire surface of the island (2). A wiring (13), a device hole (11), and a through hole (15) are formed on the second insulating sheet (10), and the insulating sheet (10) is formed of an insulating resin on the first insulating sheet (10) of the device hole. The semiconductor element (30a) is mounted via the adhesive (20), and the semiconductor element (30b) is also mounted on the insulating sheet (10) of the second layer via the adhesive (20) made of insulating resin. This is a semiconductor package. A signal from the input / output terminal of the semiconductor element (30a) mounted in the device hole enters the input end portion of the first layer wiring (13) by the wire bonding (33), and passes through the first layer through the wiring. This is a semiconductor package that is transmitted to the lead end of the wiring (13) and is transmitted from the lead end to the lead (3) by wire bonding (33). The signal from the input / output terminal of the semiconductor element (30b) mounted on the outermost surface is directly connected to the input end of the first layer wiring (13) by the wire bonding (33) passing through the through hole (15) or directly. Wire bonding (33) is connected to the input end of the second layer wiring (13), and the first layer wiring (13) or the second layer wiring (13) is connected via the wiring. It is a semiconductor package that is sent to the lead end and is transmitted from the lead end to the lead (3) by wire bonding (33).

  The materials used in the multilayer composite lead frame of the present invention will be described. The insulating sheet can be processed into a film shape, and any electrical insulating material having excellent heat resistance can be used. In general, a soft insulating resin film such as a polyimide resin is used in terms of processability and the like. When emphasis is placed on improving wire bondability when a semiconductor element is mounted, a hard insulating resin thin film plate made of ceramics, glass epoxy resin or the like can also be used. As for the thickness of the insulating sheet, it can be formed without increasing the thickness of the multi-layer composite lead frame itself by appropriately selecting from 25 μm to 100 μm, and the wiring on the insulating sheet can be appropriately formed such as a signal line, a power line, a ground line, etc. A desired number of layers can be stacked for proper use according to the purpose.

  As a material for forming the wiring part for forming the wiring, a thin film made of copper, such as a copper foil, or a metal thin film by electroplating can be used. Copper, tin, nickel, gold, silver or the like can be used as the metal. The material thickness for forming the wiring part is appropriately selected from 10 μm to 25 μm. The wiring may be a composite layer in which a metal thin film having a thickness of 0.1 μm to 2.5 μm is formed by electroplating on the surface of the wiring, and may be appropriately selected and used depending on the application.

  Next, as the adhesive, an insulating resin having heat resistance or a film is used, and an epoxy resin, an acrylic resin, a silicone resin, or the like can be appropriately selected as the resin. The thickness of the adhesive is appropriately selected from 5 μm to 50 μm and used. Bonding using an adhesive can be performed by inserting the adhesive between both sheets to be bonded and heating and pressing at a predetermined temperature and pressure.

Next, the manufacturing method will be described with reference to FIG. First, a lead frame as a base was manufactured using a normal material by a known manufacturing method. The base material was a general copper material or 42 alloy material, and a thickness of 0.15 mm was used. The apparatus uses a continuous production type etching apparatus, and a dry film is bonded to both surfaces of the material, a resist layer is formed, and a photomask on which the front and back patterns of the resist surface are formed is adhered to both surfaces. A lead frame was manufactured by developing, etching, and stripping treatment after irradiation exposure of cm ² .

Next, a first insulating sheet and a second insulating sheet were respectively produced. As the first insulating sheet, an 18 μm thick copper foil was laminated on a 50 μm thick polyimide resin film. The apparatus uses an etching apparatus for a flexible wiring board of a continuous production system, and after applying a positive resist of 0.1 μm thickness on the copper surface, irradiation exposure of 30 mJ / cm ² through a photomask, development Then, a first insulating sheet was produced by etching and stripping treatment. The wiring on the sheet was formed with a width of 20 μm, and a partial gold plating was formed on the surface of the copper wiring to form a wiring portion serving as a signal line. Next, the 2nd insulating sheet used what bonded together 18-micrometer-thick copper foil on the 50-micrometer-thick polyimide resin film. The apparatus uses an etching apparatus for a flexible wiring board of a continuous production system, and after applying a positive resist of 0.1 μm thickness on the copper surface, irradiation exposure of 30 mJ / cm ² through a photomask, development Then, a second insulating sheet was produced by etching and film removal treatment. The wiring on the sheet was formed with a width of 20 μm, and a partial gold plating was formed on the surface of the copper wiring to form a wiring portion serving as a power line and a ground line.

  Next, the first and second insulating sheets are cut to predetermined dimensions, and the first and second layers are formed on the islands of the lead frame via an adhesive made of an epoxy resin film having a thickness of 30 μm. The multi-layer composite lead frame was completed.

It is explanatory drawing of the semiconductor package using the multilayer composite lead frame of this invention, and is sectional drawing. It is a partial top view explaining the input / output destination of the wiring on the insulating sheet of the multilayer composite lead frame of the present invention. It is a partial sectional side view of one Example of the semiconductor package using the multilayer composite lead frame of this invention. It is a partial sectional side view of one Example of the semiconductor package using the multilayer composite lead frame of this invention. It is a partial sectional side view of one Example of the semiconductor package using the multilayer composite lead frame of this invention. It is the elements on larger scale which show the conventional composite lead frame, (a) is a top view of a lead frame, (b) is a top view of an insulating sheet, (c) is a sectional side view of an insulating sheet, (d) is FIG. 5E is a side sectional view of the composite lead frame, and FIG. 5E is a side sectional view of a semiconductor package on which a semiconductor element is mounted.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Lead frame 2 ... Island 3 ... Lead 4 ... Frame 10 ... Insulating sheet 11 ... Device hole 13 ... Wiring 14 ... Wiring part 15 ... Through-hole 20 ... Adhesive 30, 30a, 30b ... Semiconductor element 33 ... Wire bonding 101 ... first-layer wiring section 102 ... second-layer wiring section 131a ... first-layer wiring input terminal 131b ... first-layer wiring output terminal 132a ... first-layer wiring input terminal 132b ... first-layer wiring input terminal 132b Wiring output terminal

Claims (7)

  A plurality of leads are arranged on the island and its outer peripheral part, and a lead frame made of a metal material in which the island and the lead are integrated is used as a main body, and a plurality of insulating sheets on which the wiring parts are arranged are arranged on the island via an adhesive. In a multilayer composite lead frame that is laminated, a multilayer composite in which an insulating sheet in which a plurality of wiring portions are formed by connecting the input end portion and the output end portion arranged on the surface through the wiring is sequentially laminated to a plurality of layers. The lead frame is characterized in that the wiring portion is freely arranged and formed on the entire surface of the island, and at least the entrance and exit portions of each layer are exposed on the surface of the multilayer composite lead frame. Multi-layer composite lead frame.   2. The insulating sheet according to claim 1, wherein a wiring portion in which a plurality of wirings in which an input end portion and an output end portion are conducted through wiring are formed, and a through hole and / or a device hole are formed. Multi-layer composite lead frame.   At least the lowermost insulating sheet is an insulating sheet in which only a wiring portion is formed without a through hole and a device hole, and is attached to the entire surface of the island, or The multilayer composite lead frame according to 2.   The through hole and device hole of the insulating sheet in which the wiring portion, the through hole, and the device hole are formed are formed in the same shape and at the same position in all the insulating sheets arranged above the insulating sheet. The multilayer composite lead frame according to any one of claims 1 to 3.   A lead frame made of a metal material in which a large number of leads are arranged on the island and its outer periphery, and the island and the lead are integrated, and an insulating sheet layer on which the wiring portion is arranged is disposed on the island via an adhesive. 5. A semiconductor package in which a semiconductor element is mounted on a multi-layered multi-layer composite lead frame, wherein at least one of the multi-layer composite lead frame has an insulating resin on the insulating sheet of the multi-layer composite lead frame according to claim 1. A semiconductor package comprising the above semiconductor element.   6. The semiconductor package according to claim 5, wherein the semiconductor element is also mounted on an insulating sheet other than the uppermost insulating sheet.   The lead of the lead frame and the input / output terminal of the semiconductor element are connected and connected by wire bonding through the input end portion and the output end portion of the wiring of the insulating sheet, or 6. The semiconductor package according to 6.

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