JP2007251218A - Manufacturing method of power mosfet and power mosfet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress external resistance of a power MOSFET. <P>SOLUTION: On a first face of a pellet 10 of a power MOSFET, a source electrode pad 20 and a gate electrode pad 19 are arranged, and on a second face thereof a drain electrode pad 21 is arranged. Inner leads 37, 36 and 35 are connected to the source electrode pad 20, the gate electrode pad 19 and the drain electrode pad 21, respectively, and outer leads are connected to them, respectively, corresponding to the inner leads. The source electrode pad 20 is electrically and mechanically connected to the inner lead 37 at a source joint 22 where the inner lead 37 is branched into multiple leads. The pellet 10 and the inner leads 37, 36 and 35 are sealed with a resign sealing body 44. By connecting the source electrode to the inner lead at multiple joints, the external resistance is reduced. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a power MOSFET, and in particular, to a technique for reducing electrical resistance and thermal resistance, and for example, to an effective one for use in a power MOSFET with high output and high heat generation.

In general, high-output and high-heat generation semiconductor devices such as power transistors and power ICs are used in all fields of electronic devices and electric devices such as battery drive power supplies and switches, automotive electrical components, and motor drive control devices. Yes. Patent Document 1 is an example in which a conventional power transistor is described among such high output and high heat generation semiconductor devices. In this power transistor, a header for heat dissipation is integrally formed on a lead frame, and a pellet is fixed on the header, and the electrode pad and inner lead of the pellet are electrically connected by a bonding wire. The pellet, the inner lead group, and a part of the header are resin-sealed by a resin sealing body.
JP 59-25256 A

  In the conventional power transistor, the total of the electrical resistance of the bonding wire and the electrical resistance of the aluminum wiring of the pellet (hereinafter referred to as external resistance) and the resistance within the pellet (hereinafter referred to as internal resistance). Becomes the on-resistance of the entire power transistor. Here, the external resistance component hardly poses a problem at the stage where the internal resistance component is large. However, when technological innovation progresses and the internal resistance component is reduced and improved, and the external resistance component exceeds about 50% of the total, the external resistance component cannot be ignored.

  An object of the present invention is to provide a power MOSFET capable of suppressing an external resistance component and a manufacturing method thereof.

  The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Typical means for solving the above-described problems are as follows.

That is, a power MOSFET having a pair of surfaces and having a source electrode and a gate electrode disposed on the first surface which is one surface and a drain electrode disposed on the second surface which is the other surface is provided. Semiconductor pellets,
An inner lead connected to each of the source electrode, the gate electrode and the drain electrode;
An outer lead connected to each inner lead,
A sealing body for sealing the semiconductor pellet and the inner lead;
The source electrode is electrically and mechanically connected to the inner lead connection;
In the connecting portion, the inner lead has a shape branched into a plurality of parts.
Power MOSFET.

  According to the power MOSFET described above, the external resistance can be suppressed.

  1A and 1B show a power MOSFET according to an embodiment of the present invention. FIG. 1A is a partially cut plan view, and FIG. 1B is a front sectional view. FIG. 2 and subsequent figures are explanatory diagrams for explaining a method of manufacturing a power MOSFET according to an embodiment of the present invention.

  In this embodiment, a power MOSFET (hereinafter referred to as a transistor) 1 according to the present invention includes a semiconductor pellet (hereinafter referred to as a pellet) 10 in which a MOSFET is formed and formed into a small flat plate shape, and the MOSFET is electrically connected. Three inner leads 35, 36, and 37 for pulling out to the outside, a header 41 for improving heat dissipation performance, a resin sealing body 44 for resin-sealing the pellet 10, the inner lead group, and a part of the header 41 And. The main surface (hereinafter referred to as the upper surface) of the pellet 10 on which the circuit elements are formed is electrically and mechanically connected to the inner leads 35, 36, and 37 by connecting portions 25, 26, and 27 formed of bumps. Connected. A header 41 is coupled to the lower surface, which is the main surface on the opposite side of the pellet 10. The transistor 1 is manufactured by a manufacturing method as described below.

  Hereinafter, a method for manufacturing a transistor according to an embodiment of the present invention will be described. From this description, details of the configuration of the transistor 1 will be clarified.

  In this transistor manufacturing method, the pellet 10 shown in FIG. 2, the multiple lead frame 30 shown in FIG. 3, and the header shown in FIG. Each is prepared in the header preparation process.

  The pellet 10 shown in FIG. 2 is formed by dicing into a small square thin plate after a power MOSFET circuit is appropriately formed in a wafer state in a so-called pre-process in the manufacturing process of a semiconductor device. , Was produced. The pellet 10 includes a substrate 11, and a gate 12 is formed on the substrate 11 with polysilicon and an underlying silicon oxide film 13. A source 14 as a semiconductor diffusion layer is formed inside the substrate 11 corresponding to the outside of the gate 12 in the substrate 11, and a drain 15 is formed below the substrate 11.

  An insulating film 16 made of a CVD oxide film or the like is formed on the substrate 11 so as to cover the gate 12 and the source 14. A gate contact hole 17 is provided at a position facing the gate 12 in the insulating film 16. Is opened to penetrate through the gate 12. Further, in the region facing the source 14 in the insulating film 16, three source contact holes 18 are arranged in a direction orthogonal to one side of the gate contact hole 17 so as to penetrate the source 14. Yes.

  Further, a gate electrode pad 19 is formed inside the gate contact hole 17, and a source electrode pad 20 is formed inside each source contact hole 18. These electrode pads 19 and 20 are formed by depositing an aluminum material (aluminum or an alloy thereof) on the insulating film 16 by an appropriate means such as sputtering vapor deposition and then patterning it by photolithography. It is. That is, since the aluminum material deposited on the insulating film 16 is filled in the contact holes 17 and 18, the electrode pads 19 and 20 formed by the filling portions are respectively connected to the gate 12 and the source 14. Are electrically connected to each other. On the other hand, an electrode pad 21 for the drain 15 is deposited on the lower surface of the substrate 11 with an aluminum material.

  On the gate electrode pad 19 and the three source electrode pads 20, a protective film 24 made of an insulating material such as phosphosilicate glass or polyimide resin is applied. The gate bumps 22 and the source bumps 23 project from the positions facing the electrode pads 19 and the source electrode pads 20, respectively. The bumps 22 and 23 include first base layers 22a and 23a made of titanium (Ti) or the like, second base layers 22b and 23b made of palladium (Pd) or the like, and a main body 22c made of solder (Sn—Pb). 23c.

  The multiple lead frame 30 shown in FIG. 3 uses a thin plate made of a material having good conductivity such as iron-nickel alloy, phosphor bronze, or a copper alloy of the same material as the header, and is stamped or etched. It is integrally formed by appropriate means such as processing. A plating process using tin (Sn), gold (Au), solder (Sn—Pb), or the like is applied to the surface of the multiple lead frame 30 by an electric and mechanical mechanism using bumps 22 and 23 protruding from the pellet 10. It is attached (not shown) so that the mechanical connection is properly performed. In this multiple lead frame 30, a plurality of unit lead frames 31 are arranged in a line in one direction. However, only one unit is shown.

  The unit lead frame 31 includes a pair of outer frames 32 in which positioning holes 32a are formed. Both outer frames are arranged in parallel at predetermined intervals and extend in series. A pair of section frames 33 are arranged parallel to each other between the outer frames 32 and 32 between the adjacent unit lead frames 31 and 31, and are formed by these outer frames and section frames. A unit lead frame 31 is formed in a substantially rectangular frame.

  In each unit lead frame (hereinafter, also referred to as a lead frame) 31, a dam member 34 is provided between the section frames so as to be orthogonal to each other at a substantially central portion. Three inner leads 35, 36, and 37 are arranged on the dam member 34 at equal intervals in the length direction and project at right angles in one direction. A drain connection piece 35a is bent in an L shape in the thickness direction at the tip of a central inner lead (hereinafter referred to as a first inner lead) 35. At one end of one side inner lead (hereinafter referred to as second inner lead) 36, a gate connection piece 36a is formed in a square shape in the same plane. At the tip of the other inner lead 37 (hereinafter referred to as a third inner lead) 37, a source connection piece 37a is formed in a Y-shape in the same plane.

  In the dam member 34, three outer leads 38, 39, and 40 are arranged at positions facing the three inner leads 35, 36, and 37, respectively, so as to protrude linearly from the inner leads. ing. And between adjacent outer leads and both section frames 33 and 33, the dam 34a for damming the flow of resin at the time of fabrication of the resin sealing object mentioned below is formed, respectively.

  The header 41 shown in FIG. 4 is made of a material having good conductivity and thermal conductivity such as a copper material (copper or copper alloy), and is formed in a rectangular plate shape larger than the pellet 10. An attachment hole 42 for attaching this transistor to a printed wiring board or the like is provided in the header 41 so as to be arranged in the center near one short side and penetrate in the thickness direction.

  The pellet 10 and the header 41 prepared in advance as described above are the main surface of the pellet 10 on the drain electrode pad 21 side on one main surface (hereinafter referred to as the upper surface) of the header 41 in the pellet bonding step. Are bonded by a soldering layer 43 as a pellet bonding layer. As a solder material for forming the soldering layer 43, a solder material having a melting point equal to or higher than that of the solder material used for the bumps 22 and 23 of the pellet 10 is used. In addition, as a method for forming the soldering layer 43, a method in which the pellet 10 is pressed against a solder foil (not shown) placed on the upper surface of the header 41 and heated can be used.

  Next, in the inner lead bonding step, as shown in FIG. 5, the inner lead group is bonded to the main surface of the pellet 10 opposite to the header 41. At this time, the multiple lead frame 30 is advanced in one direction by an inner lead bonding apparatus (not shown). In the inner lead bonding stage disposed in the middle of the multiple lead frame 30 that is advanced, the pellet 30 is opposed to the unit lead frame 31 from below, and the bumps 22 and 23 are respectively connected to the inner leads. The multi-lead frame 30 is assembled by being aligned with the connection pieces 36a and 37a of 36 and 37 and thermocompression bonded with a bonding tool.

  That is, when the bumps 22 and 23 are pressed against the inner leads 36 and 37 under heating, the solder of the bump bodies 22 c and 23 c is melted and welded to the inner leads 36 and 37. After the solder is solidified, the gate connection portion 25 and the source connection are provided between the gate electrode pad 19 and each source electrode pad 20 of the pellet 10 and the second inner lead 36 and the third inner lead 37. Each part 26 is formed. The gate electrode pad 19 and the second inner lead 36 are electrically and mechanically connected by the gate connecting portion 25, and the source electrode pad 20 and the third inner lead 37 are electrically and mechanically connected by the source connecting portion 26. In addition to being mechanically connected, these mechanical connections result in a state in which the pellet 10 is mechanically connected to the lead frame 31, that is, a state in which it is fixedly assembled.

  During this inner lead bonding operation, the drain connection portion 35a of the first inner lead 35 is soldered near the short side of the header 41 opposite to the mounting hole 42. The solder connection portion forms the drain connection portion 27, and the drain connection portion 27 electrically connects the drain electrode pad 21 of the pellet 10 and the header 41.

  In the assembly of the header-equipped pellets 10 and the multiple lead frames 30 assembled as described above, the resin sealing body 44 made of an insulating resin such as an epoxy resin in the resin sealing body molding step is shown in FIG. The unit lead frames 31 are simultaneously molded using the transfer molding apparatus 50 shown in FIG.

  The transfer molding apparatus shown in FIG. 6 includes a pair of an upper mold 51 and a lower mold 52 that are clamped together by a cylinder device or the like (not shown), and the upper mold 51 and the lower mold 52 are aligned. In the surface, a plurality of sets (only one set is shown) are immersed so that the upper mold cavity recess 53a and the lower mold cavity recess 53b cooperate with each other to form the cavity 53. . Further, the mounting hole forming convex portions 60a and 60b for forming the mounting holes in the resin sealing body abut each other on the ceiling surface of the upper mold cavity concave portion 53a and the bottom surface of the lower mold cavity concave portion 53b. In addition, each of the projections has a planar shape that is equal to the mounting hole 42 of the header 41.

  A pot 54 is opened on the mating surface of the upper mold 51, and a plunger 55 that is advanced and retracted by a cylinder device (not shown) feeds resin (hereinafter referred to as resin) as a molding material to the pot 54. Has been inserted to get. On the mating surface of the lower mold 52, a cull 56 is disposed at a position opposed to the pot 54 and is recessed, and a plurality of runners 57 are radially disposed so as to be connected to the pot 54. ing. The other end of each runner 57 is connected to the lower cavity recess 53 b, and a gate 58 is formed at the connecting portion so that the resin can be injected into the cavity 53. In addition, a rectangular shape slightly larger than the outer shape of the multiple lead frame 30 is provided on the mating surface of the lower die 52 so that the escape recess 59 can escape the thickness of the unit lead frame 31. It is immersed in the depth.

The molding operation of the resin sealing body by the transfer molding apparatus configured as described above will be described.
The assembly according to the above configuration is arranged and set so that the pellet 10 is accommodated in the lower cavity 53b in the escape recess 59 submerged in the lower mold 52, respectively. Subsequently, the upper mold 51 and the lower mold 52 are clamped, and the resin 61 is fed from the pot 54 by the plunger 55 to the respective cavities 53 through the runner 57 and the gate 58 and press-fitted.

  After the injection, when the resin 61 is thermoset and the resin sealing body 44 is molded, the upper mold 51 and the lower mold 52 are opened, and the resin sealing body 44 is ejected by ejector pins (not shown). Mold is released.

  FIG. 7 shows an assembly of the multiple lead frame 30 and the resin sealing body 44 after release. Inside the resin sealing body 44 of this assembly, the pellet 10, the three inner leads 35, 36, and 37, and a part of the header 41 coupled to the lower surface of the pellet 10 are also resin-sealed. It has become. In this state, the header 41 is in a state where the end surface opposite to the pellet mounting surface is exposed from the surface of the resin sealing body 44, and the three outer leads 38, 39, 40 are formed on the resin sealing body 44. It protrudes at a right angle from one side of the short side. Moreover, the attachment hole 45 is the state opened and formed by the convex parts 60a and 60b in the site | part facing the header attachment hole 42 of the resin sealing body 44. FIG.

  In the assembly in which the resin sealing body 44 is molded as described above, the outer frame 32, the section frame 33, and the dam 34a are cut off in a lead frame cutting process (not shown). As a result, the transistor 1 shown in FIG. 1 is manufactured.

According to the embodiment, the following effects can be obtained.
(1) Since each inner lead is electrically and mechanically connected to the pellet by each connecting portion, the electrical connection by the bonding wire can be abolished. Therefore, the external resistance component is smaller than that by the bonding wire. Can be significantly reduced, and the performance of the power transistor can be enhanced.

(2) Since the power transistor package can be reduced in size and weight by eliminating the connection by the bonding wire, the performance of the power transistor can be improved in combination with (1).

(3) Since the header is separate from the inner lead group, it is possible to improve the heat dissipation performance of the header by forming the header using a material with good heat dissipation performance regardless of the inner lead material. In addition, the inner lead can be selected with the optimum material for the inner lead characteristics regardless of the header material, and the quality and reliability of the power transistor can be further enhanced.

(4) By providing a plurality of connection pieces of the source electrode pad and the source inner lead, a large current can be passed through the source, so that the performance of the power transistor can be further enhanced.

(5) By molding the resin sealing body by the transfer molding method, it is possible to improve the performance that the resin sealing body should have, such as moisture resistance, so that the quality and reliability of the power transistor can be improved.

  FIG. 8 shows a power MOSFET according to another embodiment of the present invention, in which (a) is a partially cut plan view and (b) is a front sectional view.

  The second embodiment is different from the first embodiment in that the resin sealing body 44A is molded by a potting method. That is, the resin sealing body 44A by the potting method is in a state where only the necessary portions around the pellets of the pellet 10, the inner leads 35, 36, and 37 and the header 41 are resin-sealed. Then, when molding the resin sealing body 44A, each inner lead 36, 37 is made of an insulating adhesive tape or the like in order to prevent an external force from being inadvertently applied to the inside of each inner lead 36, 37 and being deformed. It is bonded to the header 41 by an adhesive 46.

  According to the second embodiment, since the resin sealing body 44A is molded by the potting method, the cost can be reduced as compared to the case where the resin sealing body is molded by the transfer molding method, and the entire package is also obtained. Can be further reduced in size and weight.

  Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Nor.

  For example, the bumps are not limited to be disposed on the pellet side, but may be disposed on the inner lead side. Further, the bump body is not limited to being formed of solder, but may be formed of gold and connected to the inner lead by a gold-tin eutectic layer.

  The pellet and the header are not limited to be bonded by a soldering portion, but may be bonded by a gold-tin eutectic layer or a conductive adhesive layer (silver paste layer or the like). However, it is desirable to form a joint portion with good thermal conductivity in consideration of the heat radiation effect on the header of the pellet.

  The drain electrode pad is not limited to being disposed on the second main surface (lower surface) side of the pellet and electrically connected to the header, but is disposed on the same side as the gate electrode pad and the source electrode pad. The lead may be electrically connected by a connecting portion using a bump.

  The header is not limited to being bonded to the pellet before the inner lead bonding, but may be bonded to the pellet after the inner lead bonding or simultaneously with the inner lead bonding.

  The shape, size, structure, etc. of the header correspond to various conditions such as required heat dissipation performance, mounting form (for example, whether or not a presser or fastening bolt is used), pellet performance, size, shape, structure, etc. It is desirable to select them, and if necessary, heat radiating fins, bolt insertion holes, female screws, and the like can be provided.

  The material for forming the header is not limited to a copper-based material, and other metal materials having good thermal conductivity such as an aluminum-based material can be used. In particular, it is desirable to use a material such as silicon carbide (Sic) that has excellent thermal conductivity and a thermal expansion coefficient substantially equal to that of silicon, which is a pellet material.

  In the above description, the case where the invention made mainly by the present inventor is applied to the power transistor which is a field of use as the background has been described. However, the present invention is not limited to this, and the power IC, insulated gate bipolar is not limited thereto. -It can be applied to all semiconductor devices such as transistors (IGBT) and transistor arrays. In particular, an excellent effect can be obtained by using it for a semiconductor device that is required to have a high output and a low price and that also requires a high heat dissipation performance.

  The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.

  By connecting the inner leads to the pellets electrically and mechanically by the connecting part, the external resistance can be greatly reduced compared to the electrical connection by bonding wires, and the package can be reduced in size and weight. Therefore, the performance of the power MOSFET as a whole can be improved.

1 shows a power MOSFET according to an embodiment of the present invention, in which (a) is a partially cut plan view and (b) is a front sectional view. The pellet used for the manufacturing method of power MOSFET which is one Embodiment of this invention is shown, (a) is a top view, (b) is front sectional drawing. Similarly, a multiple lead frame is shown, (a) is a partially omitted plan view, and (b) is a front sectional view. The header after pellet bonding is shown, (a) is a top view, (b) is front sectional drawing, (c) is a partially abbreviated partially cut-away enlarged side view. It shows after inner lead bonding, (a) is a partially omitted plan view, (b) is a front sectional view. The resin sealing body shaping | molding process is shown, (a) is front sectional drawing, (b) is sectional drawing which follows a bb line. It shows after molding of the resin sealing body, (a) is a partially omitted plan view, and (b) is a front sectional view. The power MOSFET which is other embodiment of this invention is shown, (a) is a partially cutaway top view, (b) is front sectional drawing.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Power transistor (power MOSFET), 10 ... Pellet, 11 ... Substrate, 12 ... Gate, 13 ... Silicon oxide film, 14 ... Source, 15 ... Drain, 16 ... Insulating film, 17 ... Contact hole for gate, 18 ... Contact hole for source, 19 ... Electrode pad for gate, 20 ... Electrode pad for source, 21 ... Electrode pad for drain, 22 ... Bump for gate, 23 ... Bump for source, 24 ... Protective film, 25 ... Connection for gate, 26 ... Source connection, 27 ... Drain connection, 30 ... Multiple lead frame, 31 ... Unit lead frame, 32 ... Outer frame, 33 ... Section frame, 34 ... Dam member, 35, 36, 37 ... Inner lead , 38, 39, 40 ... outer lead, 41 ... header, 42 ... mounting hole, 43 ... soldering layer (pellet bonding) ), 44... Resin sealing body by transfer molding method, 44 A... Resin sealing body by potting method, 45... Mounting hole, 46 .. adhesive material, 50. ... cavity, 54 ... pot, 55 ... plunger, 56 ... cal, 57 ... runner, 58 ... gate, 59 ... recess, 60a, 60b ... projection, 61 ... resin.

Claims (4)

The source electrode of the semiconductor pellet having a source electrode and a gate electrode arranged on the main surface on the side where the circuit element of the semiconductor pellet is formed, and a drain electrode arranged on the main surface opposite to the main surface, In a method of manufacturing a power MOSFET in which a plurality of inner leads are connected to each of a gate electrode and the drain electrode,
Electrically and mechanically connecting the source electrode to the inner lead through a connection portion having a large connection plane area;
A method for manufacturing a power MOSFET, comprising: Semiconductor provided with a power MOSFET having a pair of surfaces and having a source electrode and a gate electrode disposed on the first surface which is one surface and a drain electrode disposed on the second surface which is the other surface Pellets,
An inner lead connected to each of the source electrode, the gate electrode and the drain electrode;
An outer lead connected to each inner lead,
A sealing body for sealing the semiconductor pellet and the inner lead;
The source electrode is electrically and mechanically connected to the inner lead connection;
In the connecting portion, the inner lead has a shape branched into a plurality of parts.
Power MOSFET. The branches are divided into a plurality of rows, one end of each branch is connected, and the width of each branch portion connected to the source electrode is wider than the interval between the branches.
The power MOSFET according to claim 2. The plurality of branches is three.
Power MOSFET.

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