JP2000216190A - Bonding tool and bonding method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To find out bonding conditions different from the ones used usually with a bare wire, by materializing the shape of the bonding tool of an insulating cover bonding wire where the inferiority in joining of bond (second bond in, the ball bonding method, and first and second bonds in the wedge bonding method) at wedge bonding or wire breaking does not occur. SOLUTION: A bonding tool 1 has such a form that the inside chamber angle is not less than 125 deg. and not more than 180 deg., and that the edge of the boundary A between an inside chamfer and the bottom smooth part of the bonding tool is rounded, etc. Moreover, as a bonding method, a method of applying ultrasonics to a board from before the bonding tool 1 contacting with the board, setting the search speed to 20 mm/sec or under, setting the search load value to not less than the 10 g and not more than 40 g, and setting the time from the moment of the bonding tool 1 contacting with the board to its shifting to the regular load (maximum load) to 10 msec or over, etc., is used.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated circuit device (I
The present invention relates to a bonding tool and a bonding method using bonding wires for connecting electrodes on C, LSI, transistors, and the like, and conductor wiring of a circuit wiring board (a lead frame, a ceramic substrate, a printed circuit board, etc.).

[0002]

2. Description of the Related Art As a method of connecting an integrated circuit element to a circuit wiring board, a ball bonding method, a wedge bonding method, a solder connection method, a resistance welding method, or the like is performed. Among them, a gold fine wire bonding wire is used. The ball bonding method used and the wedge bonding method using a bonding wire of a thin aluminum wire or a fine gold wire are generally used.

[0003] The ball bonding method has advantages such as high-speed bonding, the wedge bonding method can reduce the loop, and can perform bonding at a low substrate temperature. A general ball bonding process is as follows. After a ball is formed at the tip of a wire guided by a movable capillary (hereinafter referred to as a “bonding tool”), the ball is subjected to ultrasonic vibration at an electrode on an integrated circuit element which is a first bonding point. While pressing, a bond is formed (ball bonding).
Thereafter, while pulling out the wire, the bonding tool is moved to the electrode of the circuit wiring board, which is the second bonding point, and connected in the same manner (wedge bonding; no ball is formed at this time). After the connection, the capillary is raised, the wire is clamped, and the wire is cut by pulling.

A general wedge bonding process involves bonding by wedge bonding without forming a ball not only at the second bonding point but also at the first bonding point, and the shape of the bonding tool is different from that of the ball bonding method. ing. With the recent increase in integration and the increase in the number of pins, the distance between bonding wires is becoming narrower, and the wire span tends to be longer. As a result, there is a problem that the risk of short-circuit between adjacent wires during resin sealing increases. There is also a tendency for the bonding wire to have a low loop due to chip size packaging. In this case, there is a risk that the wire and the element may short-circuit.
Considering use in implementations that involve such contact risks,
Bonding wires covered with an insulating polymer material have been developed (see Japanese Patent Application Laid-Open No. 59-154054).

[0005] Examples of the insulating coating material of the generally used insulating coating bonding wire include urethane resin and polyvinyl formal resin. Insulation-coated wires not only improve productivity by preventing contact short-circuits, but also do not cause short-circuits even when cross-contacted, so that the degree of freedom in circuit element design can be increased.

[0006]

When an insulated bonding wire is used in a conventional ball bonding apparatus, a polymer film is heated and sublimated on the first bond side during the formation of the ball by electric discharge and does not remain on the ball surface. Under the same bonding conditions as above, the same degree of bonding properties including bonding strength can be obtained.

However, on the second bond side, the wire is pressed directly to the substrate at the tip of the bonding tool without peeling the insulating coating, and the breaking of the insulating coating is deformed by the wire (the coating that cannot follow the deformation is broken). This is performed by ultrasonic vibration and thermal decomposition, but mainly the following two problems occur. 1
One is the problem of poor bonding of the bond, and the other is the disconnection problem in which the bond and the wire are cut before the clamp is closed after the bond is formed.

The present inventor has found the following. The cause of the bonding failure problem is the applied energy (substrate heat, load,
(Ultrasonic wave) is used to destroy the coating, so that the energy directed to the bonding between the core wire and the substrate is reduced and the bonding strength is reduced, and the bonding strength is reduced due to a part of the coating remaining at the bonding interface. It is. One of the causes of the disconnection problem
First, the bonding strength of the tail bond portion (the portion that will be peeled off from the substrate and becomes the tip of the wire when the bonding tool is raised with the clamp closed) is reduced for the same reason as the bonding failure problem. A major cause is that deformation of the wire is hindered by the presence of the insulating coating.

The above two problems are that when the load (load and ultrasonic intensity) at the time of bonding is set to be high, the frequency of defective bonding decreases but the frequency of disconnection increases. Conversely, when the load is set to be low, the frequency of disconnection decreases. There is a contradictory relationship that the frequency of defective bonding increases, and as a result, the range of conditions under which good bonding properties can be obtained is very narrow in the case of an insulating-coated bonding wire. Note that these two problems become more conspicuous as the diameter of the core wire is smaller and the insulating coating layer is thicker.

[0010] When the insulation-bonded bonding wire is used in a conventional wedge bonding apparatus, the first bond side and the second bond side have the same problems as the second bond side of the ball bonding method, that is, the problem of poor bonding and the problem of disconnection. Occurs. Note that a wedge bond (ball bonding method:
A bonding apparatus provided with a mechanism for peeling off a film before the second bond and the wedge bonding method (first and second bonds) has also been proposed, but the bonding speed is reduced.
Since the apparatus is expensive, has problems such as insufficient positional accuracy of peeling, the present invention does not provide a film peeling mechanism, that is, directly to the substrate without peeling the coating before wedge bonding Assume a bonding apparatus and method for bonding.

An object of the present invention is applied to a case where an insulating-coated bonding wire is used in a ball bonding apparatus and a case where it is used in a wedge bonding apparatus. It is an object of the present invention to realize a bonding tool and a bonding method capable of obtaining good bonding properties without causing bonding failure or disconnection of a bonding method (second bond, wedge bonding method: first and second bonds).

[0012]

First, preferred characteristics of the insulating-coated bonding wire will be described. The insulating coating bonding wire is a resin having an Tg (glass transition temperature) of 120 ° C. or lower and a Tm (melting point) of 130 ° C. or higher as an insulating coating material, an elastic modulus of 200 kg / mm ² or less as an insulating coating material, and an elongation percentage. Use at least 10% resin.

When the material has a characteristic of low Tg, it has a low elastic modulus and a high elongation state (glass transition state) due to heat from the substrate.
, The deformation of the wire is hardly hindered, and the disconnection failure is hardly caused. However, appropriate heat resistance is required in order to prevent film deterioration and insulation deterioration due to heat from the substrate during bonding. We conducted experiments with various types of insulating coatings and found that Tg was 100 when the substrate temperature was 150 ° C or lower.
Tg is 110 ° C or lower and Tm is 170 ° C when Tm is 130 ° C or higher and substrate temperature is higher than 150 ° C and 200 ° C or lower.
As described above, when the substrate temperature is higher than 200 ° C. and 250 ° C. or lower, Tg is 120 ° C. or lower, Tm is 190 ° C. or higher, and
Tg is 120 ° C or less Tm
However, it has been found that when a coating film having a temperature of 200 ° C. or higher is used, good bonding properties and good insulation retention are compatible.

Even if the resin does not have the characteristic of low Tg, a resin having characteristics of a low elastic modulus and a high elongation can hardly inhibit deformation of the wire, so that good bonding properties can be obtained. As a result of experiments with various types of insulating films, it was found that good bonding can be achieved when the elastic modulus is specifically 200 kg / mm ² or less and the elongation is 10% or more. If the elastic modulus is 170 kg / mm ² or less and the elongation is 15% or more, it is preferable to further reduce the defective rate.

For example, a polyamideimide which has been baked and cured to such an extent as to exhibit such characteristics is preferable. Further, it is more preferable to mix a polyamide imide with a polyether imide or a polyamide, since the elongation is improved. A resin satisfying the above conditions for Tg and Tm and the above conditions for elastic modulus and elongation has the best bonding property. For example, a part of aliphatic polyamide and a part of polyester are applicable. Nylon 6, nylon 7, nylon 11, nylon 12, nylon 6 for aliphatic polyamide resin
6, nylon 610, nylon 612, nylon 46, copolymerized nylon and the like. Further, urethane, polyvinyl formal, polyamide imide, polyether imide, silicone resin, fluororesin, or the like may be mixed with the above polyamide resin and used.

The core material is generally gold but is not particularly limited, and may be silver, copper, aluminum, or the like, or gold, tin, or nickel plated thereon. The diameter of the core wire is generally 15 μm to 70 μm, but is not particularly limited in the present invention. The thickness of the insulating coating greatly depends on the core wire diameter, but need not be particularly limited. Generally, 0.1 μm to 5.0 μm
The m-position is preferred. When the coating thickness is 0.1 μm or less, it is difficult to uniformly form a good coating, and the coating thickness is 5.0 μm.
With the above, the frequency of bonding failure increases because the influence of the coating material during bonding is large. It is more preferable to design the coating thickness to be about 0.3 to 2.0 μm because good bonding properties and uniform and good film forming properties can be stably secured.

In the bonding tool of the present invention, the angle of the inside chamfer (the inclined surface at the tip of the tool hole; hereinafter may be abbreviated as “IC”) (the angle near the boundary between the tool bottom surface and the inside chamfer). The inside chamfer angle is 125 degrees or more and 180 degrees or less (claim 1), and the edge of the boundary between the inside chamfer and the bonding tool bottom surface smooth portion is rounded (claim 2). Large (claims 3 to 7), the surface roughness of the inside chamfer is large (claim 8), or the face angle is 0 ° or more and 4 °.
It is characterized by the following (claim 9).

FIG. 1 is a cross-sectional view of a bonding tool used in a ball bonding apparatus, and depicts the inside chamfer angle, the size of the inside chamfer, and the face angle. A boundary portion between the inside chamfer and the bonding tool bottom surface smooth portion is indicated by a symbol A. By setting the inside chamfer angle to 125 degrees or more, the angle between the inside chamfer and the bonding tool bottom surface flat portion becomes dull. Insulation-coated bonding wires tend to break because the insulation coating hinders wire deformation, but this angle reduces the concentration of wire deformation and further reduces the stress concentration of tension on the wire, resulting in disconnection. The failure frequency can be reduced. In the case of bare wire bonding, it is common to use a bonding tool having an inside chamfer angle of 90 ° to 120 °. However, when using an insulating coating bonding wire, the bonding tool is larger than 125 ° and 180 ° or less. It is desirable to use
Those having a degree of 180 degrees or more and 180 degrees or less are more preferable because of their large effects. In order to reduce the diameter of the ball bond, it is preferable to change the value stepwise or gradually as it approaches the hole.

Further, by rounding the edge of the boundary A between the inside chamfer and the bonding tool bottom surface smooth portion, the same effect as increasing the inside chamfer angle can be obtained, so that the disconnection failure can be reduced. By setting the size of the inside chamfer and the inside chamfer angle to be large, the pressing force to the substrate at the tail bond part is strong and the transmission of ultrasonic waves is improved, and the breakdown of the insulation coating is promoted, and the bonding strength of the tail bond part And the disconnection failure can be reduced. The insulation-covered bonding wire is apt to be broken because the coating inhibits the wire deformation, but also because the wire deformation is promoted by the application of ultrasonic waves, the deformability is also improved. In the case of a bare wire, if the size of the inside chamfer and the inside chamfer angle are set to be large, a defective tail remains. However, the insulating covering bonding wire is easily cut, so that a defective tail is extremely unlikely to occur. As a result, the appropriate size of the inside chamfer of the covered wire is shifted in a larger direction than that of the bare wire.

The size of the appropriate inside chamfer depends on the wire used, the bondability of the substrate, the precision of the bonding apparatus, the pad pitch of the integrated circuit element (the shortest distance between bond points with adjacent wires), bonding conditions, and the like. When the pad pitch is 90 μm or less, and the wire diameter used (refers to the core wire diameter; the same applies hereinafter) 15 μm or more and 30 μm or less The appropriate inside chamfer size is 15 μm or more, and the wire pitch is 90 μm or more and 125 μm or less. When the diameter is 15 μm or more and 25 μm or less, the size of the appropriate inside chamfer is 18 μm or more, when the pad pitch is more than 90 μm and 125 μm or less, and when the wire diameter is more than 25 μm and 35 μm or less, the size of the proper inside chamfer is 21 μm or more and the pad pitch Is larger than 125 μm and used wire diameter is 15 μm or more 2
When the size is 5 μm or less, the size of the proper inside chamfer is preferably 25 μm or more, and when the pad pitch is larger than 125 μm and the wire diameter used is larger than 25 μm and 35 μm or less, the size of the proper inside chamfer is preferably 28 μm or more.

When the inside chamfer is set to be large, the portion of the bottom surface of the bonding tool that is applied to the bonding portion becomes small, and the frequency of defective bonding increases. It is desirable that the value of the inside chamfer does not exceed the bond length. Here, the bond length is defined as (bottom diameter−hole diameter−2 × size of inside chamfer) / 2. The size of the inside chamfer can be made smaller than that described above when the inside chamfer angle is increased, or when the bonding condition described later is used, in which the disconnection is unlikely to occur and the insulation coating is likely to break down.

That is, the pad pitch is 90 μm or less,
When the used wire diameter is 15 μm or more and 30 μm or less, the appropriate size of the inside chamfer is 12 μm or more (Claim 3). When the used wire diameter is 15 μm or more and 25 μm or less, the appropriate size of the inside chamfer is In the case of 15 μm or more (claim 4), the pad pitch is more than 90 μm and 125 μm or less, and the used wire diameter is more than 25 μm and 35 μm or less, the appropriate inside chamfer size is 18 μm or more (claim 5), and the pad pitch is more than 125 μm
When the used wire diameter is 15 μm or more and 25 μm or less, the appropriate size of the inside chamfer is 20 μm or more (Claim 6). When the pad pitch is larger than 125 μm and the used wire diameter is more than 25 μm and 35 μm or less, the appropriate size of the inside chamfer is 25 μm or more (Claim 7)
Becomes

By subjecting the surface of the inside chamfer to a surface roughening treatment, the transmission of ultrasonic energy is improved, and a decrease in disconnection failure is observed as in the case where the inside chamfer and the inside chamfer angle are set large. . In addition, the bonding tool, which is characterized by a small face angle, has a strong pressing force of the wire against the substrate and easily transmits the ultrasonic power. Therefore, the breakdown of the insulation coating is promoted, the bonding strength of the bond is increased, and the frequency of bonding failure is reduced. Reduce. In the case of bare wire bonding, it is common to use a bonding tool with a face angle of 8 degrees, but when using an insulating coating bonding wire, it is 0 degrees or more.
It is desirable to use the one below the degree.

Although the above-mentioned tool shapes have an effect even when used alone, the effect becomes more remarkable when a plurality of tools are combined. In particular, (1) the face angle is 4 degrees or less and 0 degrees or more, and (2) the inside chamfer angle is 125 degrees or more and 180 degrees or less, and (3) the inside chamfer has a pad pitch of 90 μm or less and a used wire diameter of 15 μm or more.
12 μm or more for 0 μm or less, pad pitch 90 μm
Larger than 125 μm, 15 μm or more for a wire diameter of 15 μm to 25 μm, 90 μm pad pitch
m and 125 μm or less, 18 μm or more when the wire diameter is more than 25 μm and 35 μm or less, 20 μm or more when the pad pitch is more than 125 μm and 15 μm or more and 25 μm or less and the pad pitch is 12 μm or more.
Use wire diameter larger than 5 μm and larger than 25 μm and 35
If it is less than μm, it is better to set it to 25 μm or more.

In the method of bonding an insulation-coated bonding wire according to the present invention, an ultrasonic wave is applied before the bonding tool comes into contact with the substrate (claim 16), and a search speed (lowering of the tool at the moment when the bonding tool comes into contact with the substrate). Speed) is set to 20 mm / sec or less (claim 17),
The search load value (the pressing force of the tool on the substrate at the moment when the bonding tool comes into contact with the substrate) is set to 10 g or more and 40 g or less (claim 18), and the main load (maximum load) from the moment the bonding tool comes into contact with the substrate. Is set to 10 msec or more (claim 19) or a combination thereof (claims 20-22).

If ultrasonic waves are applied before the bonding tool comes into contact with the substrate, coating destruction is promoted when the insulating tool wire comes into contact with the substrate by the bonding tool,
Since the bonding between the core wire and the substrate is facilitated, the frequency of defective bonding is reduced. For the same reason, the bonding strength of the tail bond portion is increased, so that the disconnection failure is also reduced. Insulation-coated wires are inferior to bare wires in deformability and are liable to break. However, application of ultrasonic waves promotes wire deformation, so that deformability is also improved. However, if the ultrasonic power is too strong, it may cause a disconnection failure. The ultrasonic power applied before the bonding tool comes into contact with the substrate is preferably not more than 1.5 times the power used at the time of bonding the core wire and the metal constituting the substrate after the bonding tool comes into contact with the substrate. is there.

A bonding condition in which the search speed is set to a low value, a bonding condition in which the search load value is set to a small value, or a condition in which the time from when the bonding tool comes into contact with the substrate to when the actual load (the maximum load) is set is long. In this case, the wire deformation speed is reduced, so that a disconnection failure before the clamp is closed hardly occurs.

The deformation of the metal is caused by the movement of the transition and the displacement between the crystal planes. However, when the deformation speed is low, the movement of the transition can sufficiently follow, so that stress concentration does not occur and disconnection hardly occurs. This is because the heat conduction causes the elastic modulus of the coating material to decrease and the wire deformation to occur in a state where the elongation is large, so that the degree to which the insulating coating hinders the wire deformation can be reduced.

The preferred search speed largely depends on the line used, the precision of the apparatus, the substrate used, the bonding conditions, and the bonding tool used.
20mm / sec at search speeds higher than / sec due to high defect rate
It is desirable to set the following. When it is set to 15 mm / sec or less, the decrease in the defective rate becomes more remarkable, which is more preferable.
On the other hand, if it is set to 5 mm / sec or less, the bonding time becomes long and the productivity is poor, so that it is not preferable. Of course, in terms of productivity
If 5 mm / sec or less is acceptable, it may be set to 5 mm / sec or less.

The preferred search load value is used line, device accuracy,
Although it largely depends on the substrate to be used, the bonding conditions, and the bonding tool to be used, it is desirable to set the load to 40 g or less because a search load of 40 g or more usually has a large defective rate. However, from the viewpoint of the accuracy of the apparatus, if the value is set to 10 g or less, the variation becomes large, so it is preferable to set the value to 10 g or more.
Of course, if a high-precision device is used and the variation is not a problem, it may be set to 10 g or less.

The time from the moment when the preferred bonding tool comes into contact with the substrate to the time when the main load (the maximum load) is transferred is 10 minutes.
It is desirable to set the time between msec and 100 msec. 100ms
If the value is set to ec or more, it is not preferable because the bonding time is long and the productivity is poor. Of course, if 100 msec or more is acceptable from the viewpoint of productivity, it may be set to 100 msec or more.

Although the above bonding conditions are effective even when used alone, the effect becomes more remarkable by combining a plurality of them. In particular, ultrasonic waves are applied before the bonding tool contacts the substrate, and the search load is reduced by one.
Bonding conditions for setting the search speed to 0 g or more and 40 g or less and the search speed to 20 mm / sec or less are preferable. As described above, the selection of the covering material, the selection of the shape of the bonding tool, and the selection of the bonding conditions for good bonding with the insulating coating bonding wire are listed separately, but the effect becomes more remarkable by combining these.

In particular, using a tool having a face angle of 4 ° or less and 0 ° or more and an inside chamfer angle of 125 ° or more and 180 ° or less, applying ultrasonic waves before the bonding tool comes into contact with the substrate, a search. Load 10g
The elastic modulus is 20 or less as an insulating coating material under the bonding conditions of not less than 40 g and the search speed of not more than 20 mm / sec.
If an insulated bonding wire having an elongation percentage of 0 kg / mm2 or less and an elongation of 10% or more is used, suitable bonding can be realized.

[0034]

EXAMPLES (1) The following four types of resin-coated wires were manufactured. <Polyamide-coated wire> Nylon resin (nylon
A nylon varnish prepared by dissolving 612, nylon 66, and nylon 12) in a solvent was used. The solids content is 4%. A nylon varnish is applied to the surface of the gold wire by passing a gold wire having a diameter of 25 μm supplied from the supply reel at a linear speed of 80 m / min between the felts to which the solution is supplied quantitatively. The solvent was evaporated and resin thermosetting was performed. The coating thickness is 1 μm. <PAI / PEI coated wire> A varnish prepared by dissolving PAI / PEI (a mixture of polyamideimide and polyetherimide) resin in a solvent was used. The solids content is 4%. In the production, a varnish was applied to the surface of a gold wire having a diameter of 25 μm supplied from a supply reel at a linear speed of 80 m / min, and the solvent was evaporated in a heating furnace at 360 ° C. and the resin was thermoset. The coating thickness is 1 μm. <Urethane-coated wire> A urethane varnish obtained by dissolving a urethane resin in a solvent was used. The solids content is 23%. Production is supplied from a supply reel at a linear speed of 80 m / min.
Urethane varnish is applied to the surface of a 5 μm gold wire and heated in a heating furnace 26.
Solvent evaporation and resin thermosetting were performed at 0 ° C. Coating thickness is 1μ
m.

<PVF-coated wire> A varnish obtained by dissolving a PVF (polyvinyl formal) resin in a solvent was used.
The solids content is 5%. Manufactured from supply reel at linear speed 8
A PVF varnish was applied to the surface of a 25 μm gold wire supplied at 0 m / min, and the solvent was evaporated in a heating furnace at 280 ° C. and the resin was thermally cured.

(2) Example 1-4, Comparative Example 1-3 For each of the above coating resins, a resin sheet having a thickness of 70 μm was prepared from the concentrated varnish, and the elastic modulus, elongation, Tg (glass transition temperature), Tm ( Melting point). Here, the elastic modulus and the elongation are defined by forming a varnish obtained by dissolving a resin in a solvent into a sheet and firing it (film thickness after firing is 70 μm).
Cut into strips of × 5cm, hold both ends, 10mm /
It refers to the elastic modulus at the time of elongation at the speed of a minute and the elongation at the time of cutting.
Sheet baking conditions: nylon 180 ° C 1 hour + 200 ° C
1 hour, PAI / PEI 220 ° C 2 hours, PVF, urethane 1
80 ° C. for 1 hour + 220 ° C. for 1 hour.

The conditions for wedge bonding of the wire are as follows:
Substrate temperature 280 ° C, face angle 0 °, IC angle 15
0 °, IC size 30 μm, search load 40 g, bond load 80 g, search speed 15 mm / s. The elastic modulus, elongation, Tg, and Tm of the four types of resin-coated wires and the bonding strength (the wire stretched between the lead and the chip is cut at the neck of the first bond point, and the wire ends are sandwiched by a measuring jig. While moving the second bond point in the direction of the wire end at 0.25 mm / s, simultaneously pulling the wire end directly above at a speed of 0.5 mm / s to cut the bond strength, insulating property (voltage 10 V, wire resin surface) Table 1 shows the relationship between the measurement of the continuity between the electrode and the bonding substrate electrode, and the case where there is no continuity as good insulation.)
It became like.

[0038]

【table 1】

From the above results, in Example 1 to Example 4, both the defective adhesion rate and the disconnection rate were 0. It is considered that the reason why the insulation property of Example 4 was poor was that the substrate temperature was too high compared to the Tm of the resin. (3) Example 5-8, Comparative Example 4 Wedge bonding was performed using a nylon 612 resin-coated wire. The conditions of the wedge bonding of the wire are a substrate temperature of 280 ° C., a face angle of 0 °, a search load of 40 g, a bond load of 100 g, and a search speed of 15 mm / s.

IC size of bonding tool, IC
When the correlation between the angle and the wedge bond failure rate was investigated, the results are as shown in Table 2.

[0041]

[Table 2]

It can be seen from Table 2 that the larger the IC angle, the lower the defective adhesion rate and the disconnection rate, and the larger the IC size, the lower the defective adhesion rate and the disconnection rate. (4) Examples 9-10, Comparative Example 5 Wedge bonding was performed using a urethane resin-coated wire. The conditions for the wedge bonding of the wires are as follows: the substrate temperature is 280 ° C., the face angle is 0 °, and the IC angle is 150 °.
°, IC size 30 μm, search load 40 g, bond load 100 g, search speed 15 mm / s.

The effect of rounding the edge of the boundary between the bottom surface of the bonding tool and the IC and increasing the surface roughness of the IC on the wedge bond adhesion failure rate and disconnection rate was investigated. Became.

[0044]

[Table 3]

From Table 3, it can be seen that rounding the edge reduces the disconnection rate, and that the rougher the surface of the IC reduces the disconnection rate. (5) Examples 1, 11 and Comparative Example 6 Wedge bonding was performed using a nylon 612 resin-coated wire. The conditions for the wedge bonding of the wires were as follows: substrate temperature 280 ° C., IC angle 150 °, IC size 30 μm, search load 40 g, bond load 80 g,
The search speed is 15 mm / s.

The effects on the face angle of the bonding tool, the wedge bond adhesion failure rate, and the disconnection rate were investigated, and the results are shown in Table 4.

[0047]

[Table 4]

From Table 4, it can be seen that the smaller the face angle, the lower the adhesion failure rate and the disconnection rate. (6) Examples 12, 13 and Comparative Example 7 Wedge bonding was performed using a nylon 612 resin-coated wire. The conditions for the wedge bonding of the wires are as follows: substrate temperature 250 ° C., face angle 0 °, IC angle 150
°, IC size 30 μm, bond load 100 g, pre-ultrasonic power 40, and load transfer time 10 msec.

The search load (the pressing force of the tool on the substrate at the moment when the bonding tool comes into contact with the substrate), the search speed (the descending speed of the tool at the moment when the bonding tool comes into contact with the substrate) of the bonding conditions, and the wedge bond adhesion failure Table 5 shows the relationship between the rate and the disconnection rate.

[0050]

[Table 5]

From Table 5, it can be seen that the lower the search load and the lower the search speed, the lower the rate of defective adhesion and the rate of disconnection. (7) Examples 12, 14, 15 and Comparative Example 8 Wedge bonding was performed using a nylon 612 resin-coated wire. The conditions of wedge bonding were as follows: substrate temperature 250 ° C, face angle 0 °, IC angle 150 °, I
C size 30μm, search load 40g, bond load 1
00g and a search speed of 15 mm / s.

The ultrasonic power before bonding conditions (the presence or absence of ultrasonic power when applying ultrasonic waves before the bonding tool comes into contact with the substrate), the load transfer time (the actual load (from the moment the bonding tool comes into contact with the substrate) Table 6 shows the relationship between the time required to shift to the maximum load), the wedge bond adhesion failure rate, and the disconnection rate.

[0053]

[Table 6]

From Table 6, it can be seen that the pre-ultrasonic power search reduces the defective adhesion rate and the disconnection rate, and the setting of the load transfer time decreases the defective adhesion rate and the disconnection rate.

[0055]

As described above, according to the present invention, by using a bonding tool having a suitable shape, it is possible to realize good bonding properties of an insulating-coated bonding wire. Further, by using the bonding tool under bonding conditions different from those usually used for bare wires, it is possible to realize good bonding properties of the insulating-coated bonding wires.

[Brief description of the drawings]

FIG. 1 is a sectional view of a bonding tool used for a ball bonding apparatus.

[Explanation of symbols]

1 Bonding tool used for ball bonding equipment A. Boundary between inside chamfer and flat bottom of bonding tool

Claims (27)

[Claims] 1. A bonding tool having an insertion hole for inserting an insulation-coated bonding wire, wherein the inside chamfer angle is 125 degrees or more and 180 degrees or less. 2. A bonding tool having an insertion hole for inserting an insulation-coated bonding wire, wherein an edge of a boundary portion between a tool bottom surface and an inside chamfer is rounded. 3. An insertion hole for inserting an insulation-coated bonding wire is formed, and the wire diameter of the insulation-coated bonding wire (core wire diameter; the same applies hereinafter) is 15 μm or more and 30 μm or less, and the bond pad pitch is 90 μm or less. The size of the inside chamfer is set to be equal to or greater than 12 μm and equal to or less than the bond length. 4. A bonding tool for forming an insertion hole through which an insulating coating bonding wire is inserted, wherein the wire diameter of the insulating coating bonding wire is 15 μm or more and 25 μm or less, and the bond pad pitch is larger than 90 μm and 125 μm or less. Wherein the size of the inside chamfer is set to 15 μm or more and a bond length or less. 5. A bonding method in which an insertion hole for inserting an insulating coating bonding wire is formed, and a wire diameter of the insulating coating bonding wire is larger than 25 μm and 35 μm or less, and a bond pad pitch is larger than 90 μm and 125 μm or less. A bonding tool, wherein the size of the inside chamfer is set to not less than 18 μm and not more than a bond length. 6. A bonding tool for forming an insertion hole through which an insulating coating bonding wire is inserted, wherein the wire diameter of the insulating coating bonding wire is 15 μm or more and 25 μm or less, and the bond pad pitch is larger than 125 μm. The size of the inside chamfer is set to be not less than 20 μm and not more than the bond length. 7. A bonding tool for forming an insertion hole through which an insulating coating bonding wire is inserted, wherein the wire diameter of the insulating coating bonding wire is larger than 25 μm and 35 μm or less, and the bond pad pitch is larger than 125 μm. Wherein the size of the inside chamfer is set to not less than 25 μm and not more than a bond length. 8. A bonding tool having an insertion hole for inserting an insulation-coated bonding wire, the bonding tool having a surface roughened surface of the inside chamfer. 9. A bonding tool having an insertion hole for inserting an insulation-coated bonding wire, wherein the face angle is 0 ° or more and 4 ° or less. 10. The bonding tool according to claim 9, wherein the inside chamfer angle is 125 ° or more and 180 ° or less. 11. The insulating coating material of the insulating coating bonding wire has a Tg (glass transition temperature) of 120 ° C. or less and a Tm
The bonding tool according to claim 1, wherein (melting point) is 130 ° C. or more. 12. The insulating wire bonding wire according to claim 1, wherein the elastic modulus of the insulating coating material is 200 kg / mm ² or less, and the elongation is 10% or more. Bonding tool. 13. The bonding tool according to claim 11, wherein the insulating coating material contains at least a polyamideimide resin. 14. The bonding tool according to claim 13, wherein the insulating coating material is a mixed resin of polyamideimide and polyetherimide or a mixed resin of polyamideimide and polyamide. 15. The bonding tool according to claim 11, wherein the insulating coating material is an aliphatic polyamide resin. 16. A bonding method for wedge-bonding an insulation-coated bonding wire, wherein ultrasonic waves are applied before the bonding tool comes into contact with the substrate. 17. A bonding method for wedge bonding an insulation-covered bonding wire, wherein a search speed is set to 20 mm / sec or less. 18. A bonding method for wedge bonding an insulation-bonded bonding wire, wherein a search load value is set to 10 g or more and 40 g or less. 19. A bonding method for wedge bonding an insulation-covered bonding wire, wherein a time from the moment when the bonding tool comes into contact with the substrate to the time when the bonding tool is shifted to the main load is set to 10 msec or more. 20. A bonding method for wedge bonding an insulating-coated bonding wire, wherein ultrasonic waves are applied before a bonding tool contacts a substrate, and a search speed is set to 20 mm / sec or less. Bonding method. 21. A bonding method for wedge-bonding an insulating-coated bonding wire, wherein an ultrasonic wave is applied before the bonding tool comes into contact with the substrate, and a search load is set to 10 g or more and 40 g or less. Bonding method. 22. A bonding method for wedge bonding an insulating-coated bonding wire, wherein a search speed is set to 20 mm / sec or less and a search load is set to 10 g or more and 40 g or less. 23. The insulating coating material of the insulating coating bonding wire has a Tg (glass transition temperature) of 120 ° C. or less,
23. The bonding method according to claim 16, wherein the (melting point) is 130 [deg.] C. or more. 24. The insulating wire bonding wire according to claim 16, wherein the insulating coating material has an elastic modulus of 200 kg / mm ² or less and an elongation of 10% or more. Bonding method. 25. The bonding method according to claim 23, wherein the insulating coating material contains at least a polyamideimide resin. 26. The bonding method according to claim 25, wherein the insulating coating material is a mixed resin of polyamideimide and polyetherimide or a mixed resin of polyamideimide and polyamide. 27. The bonding method according to claim 23, wherein the insulating coating material is an aliphatic polyamide resin.