JP2865400B2 - Hybrid integrated circuit device - Google Patents

Description

The present invention relates to a hybrid integrated circuit device having a multilayer metal substrate structure.

(B) Conventional technology A conventional hybrid integrated circuit device having a multilayer metal substrate structure will be described with reference to FIG.

The figure shows a cross-sectional structure of a hybrid integrated circuit device. The hybrid integrated circuit device has two insulating metal substrates (62) (64), an adhesive insulating resin layer (66), a conductive path (68), and a pad (70). ), An integrated circuit element (72), a chip element (74) such as a chip resistor or a chip capacitor, a case material (75), a pair of internal leads (76), and the like.

Anodized aluminum substrates are mainly used for the insulated metal substrates (62) and (64), and the conductive paths (68) and the pads are formed by photo-etching the copper foil adhered via the insulating resin layer (66). (70) is formed in a predetermined pattern.

The integrated circuit element (72) is made of Ag at a predetermined position of the conductive path (68).
The other chip elements (74) and external leads (not numbered) are soldered to predetermined conductive paths (68) by using a paste or the like. When the two insulated metal substrates (62) and (64) are fixed to the case material (75) such that the mounting elements are opposed to each other, the substantially L-shaped internal leads (76) are provided on the respective insulated metal substrates. (62) The internal lead (76) fixed to the pad (70) of (64) is solder-fixed to the pad (70) such that the other end of the internal lead (76) abuts and bends. This contact portion of the internal lead (76) is soldered by reflow,
The conductive paths (68) formed on the two insulated metal substrates (62) (64) are interconnected.

According to the above structure, the projected area of the hybrid integrated circuit device can be reduced, and the two insulated metal substrates (62) (6)
In any of 4), a high-power integrated circuit element can be mounted.

(C) Problems to be Solved by the Invention However, in the hybrid integrated circuit device having the above structure, a portion where the conductive paths can be interconnected is limited to an end of the insulating metal substrate. There is a problem that it must be led to the edge of the substrate. In particular, in recent hybrid integrated circuit devices equipped with a microcomputer, since the number of conductive paths requiring interconnection is enormous, there is a drawback that a large amount of element mounting area is consumed by routing these conductive paths. .

When a microcomputer of 16 bits or more is mounted, the width of the data bus and address bus cannot be traversed by a single wire bonding. Heretofore, a technique called jumping wire connection has been used for several times. For this reason, there is also a disadvantage that a large amount of device mounting area is consumed by a large number of pads for jumping wire connection.

Furthermore, in the above-mentioned hybrid integrated circuit device, since the internal leads are fixed by soldering after the respective insulated metal substrates are fixed to the case material, the manufacturing process is complicated and not only the subsequent functional test becomes difficult, but also trouble occurs. It has the drawback that shooting is impossible.

(D) Means for Solving the Problems The present invention has been made in view of the above-mentioned problems, and is provided at a predetermined position of a mother substrate formed of an insulating metal substrate.
By mounting an integrated circuit, etc. in the same manner as the mother board, and separately fixing the sub-board with conductive paths for jumping connection, and conducting interconnection between the sub-board and the conductive paths of the mother board by wire bonding, The present invention also provides a highly integrated hybrid integrated circuit device.

(E) Function In order to arrange the sub-substrate having the conductive path in a predetermined shape at a predetermined position on the mother substrate, it is possible to interconnect the sub-substrate and the conductive path of the mother substrate at an arbitrary peripheral end of the sub-substrate. It becomes possible, and the routing of the conductive path of the mother substrate is suppressed.

Further, the connection of the conductive path of the mother substrate by the conductive path of the sub-substrate can be performed over a long span. Similarly, the routing of the conductive path of the mother substrate can be suppressed, and a pad for jumping connection is not required.

Further, since the sub-substrate is fixed on the mother substrate with a distance, the entire area of the mother substrate can be used for device mounting.

Furthermore, since the main surfaces of the sub-board and the mother board face in the same direction, the function test and troubleshooting after the interconnection of the conductive paths of the sub-board and the mother board are facilitated.

(F) Embodiment An embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a plan view of the embodiment, and FIG. 2 is a sectional view taken along line II of FIG. FIG. 3 is a plan view of the sub-board.

As shown in FIGS. 1 and 2, the hybrid integrated circuit device of the present invention has a substrate structure in which a sub-substrate (30) is arranged at a predetermined position on a mother substrate (10).

The mother board (10) has anodized surface 1.5 ~
A 2.0 mm-thick aluminum substrate is used. For example, conductive paths (12) such as an address bus, a data bus, and a control bus are formed by photo-etching a copper foil adhered by an adhesive insulating resin layer (not shown). A pad (14) for wire bonding with an electrode of the integrated circuit element (22), an external lead pad (16), and a mother board (10) and a conductive path formed on the sub-board (30) are interconnected. (18) and pads (20) for fixing the support member of the sub-substrate (30) are formed in a predetermined pattern on the entire surface.

Integrated circuit elements (22) (24) (26) such as microcomputers, programmable gate arrays, memories, etc. are fixed on predetermined die bond pads using Ag paste, and power integrated circuit elements (22) that generate a particularly large amount of heat (24) is fixed via a heat sink (28). A chip element (not shown) such as a chip resistor or a chip capacitor is fixed by soldering. The sub-board (30)
The wire bonding of the electrodes of the integrated circuit element (26) disposed immediately below is performed before the sub-substrate (30) is fixed.

 Next, the sub-board (30) will be described with reference to FIG.

The figure illustrates the planar structure of the sub-substrate (30) on which circuit pattern formation and element fixation have been completed. The sub-substrate (30) has holes (32) and tabs (34) formed by press molding, Ag paste is applied on conductive paths (36), pads (38), (40), (42) and predetermined die bond pads formed by photo-etching copper foil adhered on one or both sides with the insulating resin layer of This is indicated by the integrated circuit element (46) fixed and used.

For the sub-substrate (30), a copper alloy having a thickness of approximately 0.5 mm containing tin, chromium, nickel, iron, or the like is used in consideration of solder fixation to the mother substrate (10) and strength.

The conductive path (36) of the sub-substrate (30) interconnects the circuit elements on the sub-substrate (30) and the conductive path (12) formed on the mother substrate (10) through the pads (42) and (18). Further, the conductive path (12) formed on the mother substrate (10) is simply jump-connected via the pads (42) and (18).

The tab (34) is approximately 3m from its end in the given process
It is bent at right angles to the surface of the sub-board (30) at the position of m, and the arrangement interval between the sub-board (30) and the mother board (10) is approximately
It becomes the support part (34) that regulates to 3 mm. The support portion (34) can be formed by drawing a metal of the sub-substrate (30), by using a separate support member, or simply by bending the end of the sub-substrate (30). It is also possible to form. FIG. 3 shows a sub-substrate (30) having a multi-plane configuration, but a single-plane configuration may be used.

The embodiment will be described in further detail with reference to FIGS. 1 and 2 again.

When the support portion (34) of the sub-substrate (30) is fixed to the pad (20) formed on the mother substrate (10) by soldering, a predetermined integrated circuit fixed to the mother substrate (10) as shown in FIG. The (24) is exposed from the hole (32) formed in the sub-substrate (30), and the integrated circuit element (24) and the pad (40) are arranged adjacent to each other. The reason why the holes (32) are formed in the sub-substrate (30) is that the integrated circuit element (24), which is a component of the electronic circuit of the sub-substrate (30), has a mother board (10) that has particularly excellent heat dissipation characteristics.
In the present invention in which the mother substrate (10) and the sub-substrate (30) both use a metal substrate, it is relatively free to arrange the heating element on any one of the substrates. (32) is not an essential structure of the present invention.

Pads (14) and (44) are arranged adjacent to the integrated circuit element (22), and the electrodes thereof are connected to the sub-substrate (3) as necessary.
0), it is possible to connect to any of the mother substrates (10). These integrated circuit elements (22) and (24) are fixed via a heat sink (28) so that their electrode surfaces are substantially equal in height to the surface of the sub-substrate (30), and the wire bonding efficiency is considered.

Further, the pad (42) formed on the sub-substrate (30) and the pad (18) formed on the mother substrate (10) are wire-bonded, so that the electronic circuit of the sub-substrate (30) and the mother substrate (10) are bonded. Interconnection of electronic circuits is performed, and jumping connection of conductive paths (12) formed on the motherboard (10) is performed.

As already apparent, the hybrid integrated circuit device of the present invention has a substrate structure in which the sub-substrate (30) is spaced apart from the mother substrate (10) at a predetermined position. The interconnecting process between the conductive path on (30) and the conductive path on the motherboard (10) is performed in the same manner as an integrated circuit element or a chip element fixed on the motherboard (10),
The manufacturing and testing processes excluding the casing are completed on the mother board (10). Although the hybrid integrated circuit device of the present invention is finally sealed by a case material (not shown), it can be housed in a hollow structure of a conventional case material.

Although one embodiment of the present invention has been described above, the present invention is not limited to the embodiment because various modifications can be made to the planar shape of the sub-substrate and the like.

(G) Effects of the Invention As described above, the hybrid integrated circuit device of the present invention has the following advantages. (1) Since the interconnection between the conductive path of the mother substrate and the conductive path of the sub-substrate can be made at any position, the conductive path The reduction of the mounting area due to the routing is avoided.

(2) Since the conductive path of the mother board can be connected to the conductive path of the sub-board over a long span, a pad for jumping connection is not required, and a reduction in mounting area is avoided.

(3) Since a metal substrate is used for both the mother substrate and the sub-substrate, the arrangement of the heating elements is free.

(4) Since the sub-substrate is fixed to the mother board by separation, the entire area of the mother board can be used for element mounting.

(5) Since the main surfaces of the sub-board and the mother board face in the same direction, it is easy to perform a functional test and troubleshooting after interconnecting the conductive paths of the sub-board and the mother board.

(6) Since a chip element is used as an integrated circuit, a high degree of integration is achieved.

(7) Since a copper alloy, which is easy to process, is used for the sub-substrate, the supporting portion for separation and fixing can be integrally formed.

[Brief description of the drawings]

1 is a plan view of one embodiment of the present invention, FIG. 2 is a vertical sectional view taken along the line II of FIG. 1, FIG. 3 is a plan view of a sub-substrate used in the present invention, and FIG. FIG. 2 is a plan view of the hybrid integrated circuit device of FIG. 10 ... mother board, 12, 36 ... conductive path, 14, 38, 40, 44 ... pad, 16 ... pad for external lead, 18, 42 ... pad for internal connection, 20 ... pad for support member, 22, 24, 26 ... an integrated circuit element, 30 ... a sub-substrate, 32 ... a hole, 34 ... a support member.

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Yoshiyuki Kobayashi 2-18-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Inventor Sumio Ishihara 414-1 Oma, Omamachi, Yamada-gun, Gunma Prefecture (56) References JP-A-61-136252 (JP, A) JP-A-63-273391 (JP, A) JP-A-62-260353 (JP, A) JP-A-1-305590 (JP, A) A) (58) Field surveyed (Int. Cl. ⁶ , DB name) H01L 25/00-25/18 H05K 1/14

Claims (4)

(57) [Claims] 1. A mother substrate having a conductive path made of Cu of a predetermined shape formed on a first insulating metal substrate, and at least an integrated circuit element fixedly mounted at a predetermined position of the conductive path, and a second substrate made of a Cu alloy. A conductive path is formed in a predetermined shape on the insulated metal substrate, and an integrated circuit element and / or a sub-substrate on which a chip element such as a chip resistor or a chip capacitor is fixedly mounted at a predetermined position of the conductive path; The hybrid integrated circuit device, wherein the substrate is fixed to a predetermined position on the mother substrate via a pointing member that separates the substrate by a predetermined distance, and the conductive path between the sub substrate and the mother substrate is connected by wire bonding. Or a tab formed at the end of the sub-substrate is bent to form a support member for the sub-substrate, and a copper foil is formed on the mother substrate corresponding to the support member. Wherein the support member and the copper foil are fixed by soldering. 2. A mother board on which a conductive path of a predetermined shape is formed on a first insulating metal substrate, and at least an integrated circuit element is fixedly mounted at a predetermined position of the conductive path, and a predetermined path is formed on a second insulating metal substrate. A conductive path is formed in a shape, and an integrated circuit element and / or a sub-substrate on which a chip element such as a chip resistor or a chip capacitor is fixedly mounted at a predetermined position of the conductive path. In a hybrid integrated circuit device which is fixed to a position via a supporting member which is separated by a predetermined distance and which connects a conductive path between the sub-substrate and the mother substrate by wire bonding, the hybrid substrate is provided on one side of the mother substrate. A first pad, a second pad provided on one side of the sub-substrate corresponding to the first pad, and a first pad connecting the first pad and the second pad. A thin metal wire, a third pad provided on the other side of the mother substrate, a fourth pad provided on the other side of the sub-substrate corresponding to the third pad, and the third pad And a second thin metal wire connecting the fourth pad, and a jump conductive path extending from the second pad to the fourth pad and extending to the sub-substrate. Hybrid integrated circuit device. 3. An end portion of the sub-substrate is bent or a tab formed at an end portion of the sub-substrate is bent to form a support member for the sub-substrate, and a copper foil is provided on the mother substrate corresponding to the support member. 3. The hybrid integrated circuit device according to claim 2, wherein said support member and said copper foil are fixed by soldering. 4. The hybrid integrated circuit device according to claim 1, wherein said sub-substrate contains tin, chromium, Ni or iron.