JP4616924B2 - Semiconductor device - Google Patents

Description

  The present invention relates to a semiconductor device having a wire loop shape in which a first bond point and a second bond point are connected by a wire.

  For assembling a semiconductor device, wire bonding is used to connect a pad of a semiconductor chip attached to the lead frame and a lead of the lead frame with a thin metal wire. For wire bonding, an initial ball is first formed at the tip of the wire using a wire bonding apparatus, and the initial ball is pressed against a pad of a semiconductor chip by a capillary to form a pressed ball. Then, after raising the capillary and performing a reverse operation toward the side opposite to the second bond point, the capillary is further raised to a predetermined height, and then the capillary is moved in the direction of the second bond point. A method of connecting wires to the wire is used (see, for example, FIGS. 4 to 6 of Patent Document 1).

  In this way, the wire is bonded by operating the capillary, and the wire neck extends upward from the press-bonded ball that is press-bonded to the pad of the semiconductor chip, and the inclination that is bent from the wire neck toward the second bond point. In many cases, a triangular shape including a portion or a trapezoidal shape including a horizontal portion extending substantially horizontally from the wire neck toward the second bond point and an inclined portion extending from the horizontal portion toward the second bond point. This is because if the portion close to the press-bonded ball is moved in the horizontal direction of the capillary toward the second bond point, the neck portion is damaged due to the friction generated between the capillary and the fine metal wire during the movement. This is because there are cases.

  However, since this wire loop shape includes a wire neck that rises upward from the press-bonded ball, the height of the wire loop increases, and the overall height or thickness of the semiconductor device assembled by wire bonding can be reduced. There was no problem.

  Therefore, after bonding to the first bond point, a reverse operation is performed in which the capillary is slightly raised and moved to the opposite side of the second bond point, and further, a forward operation is performed in which the capillary is slightly raised and moved to the second bond point side. The capillary is lowered and the wire neck portion is folded back onto the pressure-bonded ball and pressed, and the direction in which the wire extends is set horizontally or slightly upward from the horizontal, and then the capillary is pulled out while feeding the wire from the tip of the capillary. A method has been proposed in which the wire is connected to the second bond point by moving the capillary up to the second bond point (for example, from FIG. 1 to FIG. 3 of Patent Document 1 or FIG. 1 of Patent Document 2). (See FIG. 3).

JP 2004-172477 A JP-A-9-51011

  In the bonding method according to the prior art described in Patent Document 1 or 2, since the head is formed by folding the wire onto the press-bonded ball and then pressing the wire, the height of the head is not reduced so much. In some cases, the request to lower the wire loop height could not be met.

  Accordingly, an object of the present invention is to lower the height of the wire loop in the connection between the first bond point and the second bond point.

The semiconductor device of the present invention is a semiconductor device having a wire loop shape in which a wire is connected between a first bond point and a second bond point, and an initial ball formed at the tip of the wire is formed by the capillary with the first ball. A press-bonded ball and a ball neck formed by bonding to a bond point, a pressing portion that is folded back on the ball neck and does not protrude from the diameter of the press-bonded ball, and between the pressing portion and the second bond point The wire, and a joint between the wire and the second bond point, and the ball neck raises the capillary after the initial ball is joined to the first bond point by the capillary, Subsequently, the capillary is moved in a direction opposite to the second bond point, and then the capillary is lowered to Having a first face portion in the second part of which is formed in the disc shape even smaller diameter than the compression ball is squished plane of the ball neck bonding point side of the second bonding point side, The pressing portion lowers the capillary and steps on the part of the ball neck on the second bond point side until the surface becomes flat, and then raises the capillary, and then the capillary The capillary is moved toward the second bond point until the second face portion opposite to the second bond point is on the ball neck, and then the wire is folded toward the second bond point. The capillary is lowered and stepped on, and the wire is folded back on the part of the ball neck that has become flat, and the side surface of the wire is placed on the side of the capillary. The wire between the pressing portion and the second bond point is formed by pressing the second face portion opposite to the second bond point, and the side surface of the wire is connected to the second bond point of the capillary. And then the capillary is moved obliquely upward toward the second bond point, then the capillary is raised, and then the capillary is moved to the opposite side of the second bond point. A downwardly convex curved portion and a downwardly convex curved portion formed by moving the capillary further upward and then moving the capillary in the direction of the second bond point. A convex bent portion on the second bond point side, and the joint between the wire and the second bond point moves the capillary further to the second bond point. The wire is formed by press-bonding the wire to the second bond point.

  The present invention has an effect that the height of the wire loop can be further reduced in the connection between the first bond point and the second bond point.

It is explanatory drawing which shows the step of a wire bonding which assembles the semiconductor device in embodiment of this invention, and a pressing process. It is explanatory drawing which shows the kink formation process of a wire bonding which assembles the semiconductor device in embodiment of this invention, a 2nd bonding process, and the wire loop of embodiment of this invention. It is explanatory drawing which shows the movement of the capillary tip of the wire bonding which assembles the semiconductor device in embodiment of this invention. It is explanatory drawing which shows the step of the wire bonding which assembles the semiconductor device in other embodiments of the present invention. It is explanatory drawing which shows the movement of the capillary tip of the wire bonding which assembles the semiconductor device in other embodiment of this invention.

  Hereinafter, a preferred embodiment of the semiconductor device of the present invention will be described with reference to FIGS. As shown in FIGS. 1 and 2, in the semiconductor device of this embodiment, a wire loop 20 connects a pad 13 of a semiconductor chip 11 mounted on a lead frame 12 and a lead 17 formed on the lead frame 12. A semiconductor device to be connected. In the semiconductor device, a wire loop 20 that connects a plurality of pads 13 and leads 17 is formed. In the following description, connection between one pad 13 and one lead 17 will be described. The pad 13 of the semiconductor chip 11 is a first bond point, and the lead 17 of the lead frame 12 is a second bond point. In FIG. 1, the lead 17 is not shown, but the right side in the drawing is the lead 17 side. FIG. 3 is a diagram showing the movement of the tip of the capillary 41.

  First, an initial ball (not shown) formed on the tip end of the wire 21 by the capillary 41 is ultrasonically vibrated and pressed onto the pad 13 to form a press-bonded ball 23 and a ball neck 25 on the pad 13. A first bonding step is performed. The press-bonded ball 23 is formed by a spherical initial ball being crushed by the face portion 43 of the capillary 41 into a disk shape, and the ball neck 25 is a portion of the initial ball having the inner chamfer portion 45 and the straight hole 47 of the capillary 41. It is formed by entering and extends from the crimping ball 23 toward the wire 21 and has a cylindrical shape having a diameter substantially the same as the straight hole 47 of the capillary 41 larger than the diameter of the wire 21. When the capillary 41 is pressed against the pad 13, the tip of the capillary 41 is positioned at a point a on the press-bonded ball 23 shown in FIG.

  After the first bonding step, a stepping step as shown in FIGS. 1A to 1C is performed. In the stepping process, as shown in FIG. 1 (a), the wire 21 is fed out and the capillary 41 is raised to move the tip of the capillary 41 from point a to point b shown in FIG. Next, as shown in FIG. 1B, the capillary 41 is moved in the direction opposite to the lead 17 until the face portion 43 on the lead 17 side of the capillary 41 comes to the upper part of the ball neck 25, and the tip of the capillary 41 is illustrated. 3 from point b to point c. At this time, the wire 21 is inclined from the ball neck 25 in the direction opposite to the lead 17. Then, the tip of the capillary 41 is lowered from the point c shown in FIG. 3 to the point d, and the lead 17 side of the ball neck 25 is stepped on the face part 43 on the lead 17 side of the capillary 41 as shown in FIG. wear. By stepping, the columnar ball neck 25 becomes a disk-like stepping portion 25 a having a slightly smaller diameter than the press-bonded ball 23. The upper surface of the stepping portion 25 a on the lead 17 side is crushed by the face portion 43 of the capillary 41, and thus has a planar shape along the shape of the face portion 43. Further, the wire 21 is bent to the side opposite to the lead 17 of the stepping portion 25 a and extends in the vertical direction of the pad 13 along the inner surface of the straight hole 47 of the capillary 41 opposite to the lead 17. .

  Next, a pressing process as shown in FIG. 1 (d) to FIG. 1 (f) is performed. As shown in FIG. 1D, the wire 21 is fed out from the tip of the capillary 41, and the tip of the capillary 41 is raised from point d to point e shown in FIG. Then, the wire 21 is drawn out along a straight hole 47 of the capillary 41 in a straight line. Then, the tip of the capillary 41 is moved from the point e to the point f shown in FIG. Then, as shown in FIG. 1E, the wire 21 is pushed toward the lead 17 by the inner chamfer portion 45 of the capillary 41, and is bent at the bent portion 25b following the stepping portion 25a. Then, the capillary 41 is moved in the direction of the lead 17 until the face portion 43 on the side opposite to the lead 17 of the capillary 41 is on the press-bonded ball 23. Then, the tip of the capillary 41 is lowered from point f to point g in FIG. Then, as shown in FIG. 1 (f), the side surface of the wire 21 is pressed onto the stepping portion 25 a formed by stepping on the ball neck 25 by lowering the capillary 41. By the pressing of the wire 21, the bent portion 25b of the wire 21 is folded back toward the stepping portion 25a to form a folded portion 26a. The pad 13 side of the pressing portion 26 of the wire 21 is pressed against the upper surface of the stepping portion 25 a by pressing, and a flat surface is formed on the upper surface of the pressing portion 26 by the face portion 43 of the capillary 41. When the pressing process is completed, the capillary 41 is located closer to the lead 17 than the bonding center line 28 of the pad 13.

  When the wire 21 is pressed onto the stepping portion 25 a by the face portion 43 of the capillary 41, the capillary 41 is reciprocated in the direction of the lead 17 and the direction opposite to the lead 17 simultaneously with the pressing, thereby stepping on the wire 21. You may make it adapt to the part 25a, and you may make it press the wire 21, vibrating the front-end | tip of the capillary 41 by ultrasonic vibration.

  As shown in FIG. 2A, after the pressing step, the wire 21 is drawn from the tip of the capillary 41 to raise the capillary 41, and obliquely upward from the point g to the point h shown in FIG. An oblique ascending process is performed. By this diagonally rising process, the wire 21 is wrinkled so as to be convex toward the lead 17.

  As shown in FIG. 2B, a kink forming process is performed after the oblique ascending process. In the kink forming process, the wire 21 is pulled out from the tip of the capillary 41 and the tip of the capillary 41 is raised from the point h to the point i shown in FIG. The tip is moved from point i to point j in FIG. By this movement, the capillary 41 that is closer to the lead 17 side than the bonding center line 28 of the pad 13 at the end of the previous pressing step is positioned in a direction opposite to the lead 17. By this reverse operation, the wire 21 rising from the lead 17 side of the pad 13 becomes an inclined shape while bending in the direction opposite to the lead 17. On the other hand, since the wire 21 in the capillary 41 is held in a direction substantially perpendicular to the surface of the pad 13, the wire 21 in the vicinity of the tip of the capillary 41 in the state where the reverse operation is completed is opposite to the lead 17. A kink 34 that is convex is formed.

  As shown in FIGS. 2C to 2E, the second bonding step is performed following the reverse operation. When the tip of the capillary 41 is raised while feeding the wire 21 from the point j to the point k shown in FIG. 3, the wire 21 is fed to the tip of the kink 34 as shown in FIG. The length of the wire 21 drawn out by raising the capillary 41 is longer than the wire feeding length in the previous reverse operation. Then, the tip of the capillary 41 is moved from the point k in FIG. 3 to the point m in FIG. 3, and the capillary 41 is looped toward the lead 17 as shown in FIGS. 2 (d) and 2 (e). By this looping, the kink 34 is bent more and becomes a bent portion 27. Further, the ridges convex toward the leads 17 attached to the wires 21 by the oblique ascending process have a shape in which the wires 21 extending from the pressing portions 26 to the leads 17 are curved downwardly by looping. Then, the tip of the capillary 41 is pressed against the lead 17 to bond the wire 21 to the lead 17. When the wire 21 is joined to the lead 17, a wire loop 20 that connects the pad 13 that is the first bond point and the lead 17 that is the second bond point is formed. When all the pads 13 of the semiconductor chip 11 and all the leads 17 of the lead frame 12 are connected by the wire loop 20, the assembly of the semiconductor device is completed.

In the wire bonding for assembling the semiconductor device of this embodiment, in the stepping process, the ball neck 25 is stepped on the face portion 43 of the capillary 41 to reduce its height, and then the wire 21 is folded back to reduce the height. Since the side surface of the wire 21 is pressed on the portion 25a and then the wire 21 is looped toward the lead 17, the head of the wire loop 20 of the semiconductor device formed on the pad 13 as shown in FIG. since the height H ₁ can be lower than the loop height disclosed in the prior art, it is possible to lower the rising height of the semiconductor chip 11 of the wire loop 20. Further, in the pressing step, the side surface of the wire 21 is pressed against the substantially flat upper surface of the stepping portion 25a, so that the wire 21 extending from the pressing portion 26 toward the lead 17 is bent upward during looping. , it is possible to suppress the height H ₂ of the wire loop 20 between the pressing portion 26 and the lead 17 is increased, that the rising height of the semiconductor chip 11 of the wire loop 20 to lower it can. Furthermore, the convex ridges toward the lead 17 attached to the wire 21 in the oblique ascending process form a downward convex curved shape in the wire 21 between the pressing portion 26 and the lead 17 by looping, and the lead from the pressing portion 26 leads. wire 21 towards 17 is curved toward upward, it becomes higher height H ₂ of the wire loop 20, along with it can be prevented that the total height of the wire loop 20 is increased, the wire The overall height of the loop 20 can be uniformly reduced. In the semiconductor device of this embodiment, the pressing portion 26 does not protrude in the diameter direction of the press-bonded ball 23.

  In the wire bonding for assembling the semiconductor device of the present embodiment described above, the bending portion 27 is formed in the wire loop 20 by performing the oblique ascending step and the kink forming step after the pressing step. When there is no difference in height from the lead 17, the kink forming process is not performed, and the pad 13 and the lead 17 may be connected by performing a second bonding process after the oblique ascending process.

  Another embodiment of the present invention will be described with reference to FIGS. Parts similar to those of the embodiment described above with reference to FIGS. 1 to 3 are denoted by the same reference numerals and description thereof is omitted. The semiconductor device of the present embodiment has a wire loop 20 formed when the tip of the capillary 41 becomes thin or by wire bonding using the capillary 41 with a thin tip.

  As shown in FIG. 4, when the tip of the capillary 41 is thin, the area of the face portion 43 of the capillary 41 becomes small. For this reason, the ball neck 25 cannot be sufficiently stepped on by one stepping, and the height of the folded portion 26 of the wire 21 may become high. Therefore, as shown in FIGS. 4 and 5, after the first bonding, a series of continuous operations of raising the capillary 41, moving to the opposite side of the lead 17, lowering the capillary 41, and stepping on the ball neck are repeated twice. The ball neck 25 can be sufficiently stepped on.

  As shown in FIG. 4A to FIG. 4C, after the first bonding, the capillary 41 is raised and then the capillary 41 is moved in the direction opposite to the lead 17, and then the capillary 41 is lowered and the capillary 41 is moved down. The lead 17 side of the ball neck 25 is stepped on by the face portion 43 on the lead 17 side. In this operation, the tip of the capillary moves to point a, point b, point c, and point d shown in FIG. 5, and the horizontal movement distance from point b to point c is the face portion of capillary 41. The amount of movement is such that the side surface of the lead 17 on the side of 43 is slightly positioned on the side opposite to the side of the lead 17 than the side surface on the side of the lead 17 of the press-bonded ball 23. After the capillary 41 is horizontally moved in this way, when the capillary 41 is lowered and the ball neck 25 is stepped on, the top surface of the ball neck 25 on the lead 17 side is leveled by the face portion 43 of the capillary 41 on the lead 17 side. It can be set as the stepping part 25a.

  Then, as shown in FIGS. 4D to 4F, the capillary 41 is raised again, and then the capillary is moved horizontally to the side opposite to the lead 17, and the capillary 41 is lowered again to read the capillary 41. The area of the horizontal stepping portion 25a is increased by stepping on the ball neck 25 located on the opposite side of the lead 17 of the stepping portion 25a formed by the previous stepping by the face portion 43 on the 17th side. In this operation, the tip of the capillary moves to point d, point b ′, point c ′, and point d ′ shown in FIG. The horizontal movement distance from the point b ′ to the point c ′ is a movement amount necessary to increase the area of the horizontal stepping portion 25a.

  Then, when the two continuous operations of the stepping process are completed, as in the previous embodiment, the capillary 41 is raised and moved to the lead 17 side as shown in FIG. Thereafter, the capillary 41 is lowered and the wire 21 is pressed onto the stepping portion 25a to form the pressing portion 26, and the wire 21 is lifted obliquely upward toward the lead 17 to perform a diagonally rising step to form a kink. After performing the process, the lead 21 is looped and the wire 21 is bonded to the lead 17. In the semiconductor device of this embodiment, the pressing portion 26 does not protrude in the diameter direction of the press-bonded ball 23.

  The embodiment described above has the same effect as the embodiment described above, and can reliably form the low wire loop 20 even with the capillary 41 having a thin tip or the capillary 41 having a thin tip. In the wire bonding for assembling the semiconductor device of the present embodiment, a series of continuous operations of raising the capillary 41 in the stepping process, horizontally moving in the direction opposite to the lead 17, lowering, and stepping are repeated twice. However, the repetition of the continuous operation is not limited to two times, and may be repeated several times according to the size of the tip of the capillary 41.

  DESCRIPTION OF SYMBOLS 11 Semiconductor chip, 12 Lead frame, 13 Pad, 17 Lead, 20 Wire loop, 21 Wire, 23 Crimp ball, 25 Ball neck, 25a Stepping part, 25b Bending part, 26 Pressing part, 26a Folding part, 27 Bending part, 28 Bonding center line, 34 kink, 41 capillary, 43 face part, 45 inner chamfer part, 47 straight hole.

Claims (1)

A semiconductor device having a wire loop shape for connecting a first bond point and a second bond point with a wire,
A press-bonded ball and a ball neck formed by joining an initial ball formed at the tip of the wire to the first bond point with a capillary, and a pressing that is folded over the ball neck and does not protrude from the diameter of the press-bonded ball Part, the wire between the pressing part and the second bond point, and a joint part between the wire and the second bond point,
The ball neck is formed by joining the initial ball to the first bond point by the capillary, then raising the capillary, and subsequently moving the capillary in a direction opposite to the second bond point. A disk having a diameter smaller than that of the press-bonded ball by lowering the capillary so that a part of the ball neck on the second bond point side is stepped on the first face portion on the second bond point side of the capillary. Having a plane formed in a shape ,
The pressing portion lowers the capillary and steps on the part of the ball neck on the second bond point side until the surface becomes flat, and then raises the capillary, and then the capillary The capillary is moved toward the second bond point until the second face portion opposite to the second bond point is on the ball neck, and then the wire is folded toward the second bond point. The wire is folded over the part of the ball neck that has been flattened by being lowered and stepped on the capillary, and the side surface of the wire is opposite to the second bond point of the capillary. It is formed by pressing on the face part,
The wire between the pressing portion and the second bond point presses the side surface of the wire with the second face portion opposite to the second bond point of the capillary, Move diagonally upward toward the second bond point, then raise the capillary, then perform a reverse operation to move the capillary to the opposite side of the second bond point, and then raise the capillary further, A downwardly convex curved portion formed by moving the capillary in the direction of the second bond point and a convexly bent portion on the second bond point side of the downward convex curved portion;
The joint between the wire and the second bond point is formed by further moving the capillary to the second bond point and crimping and bonding the wire to the second bond point;
A semiconductor device characterized by the above.

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