JP2001168136A - Wire bonding method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wire bonding method in which bonding quality is prevented from lowering. SOLUTION: A capillary tool 42 held at the forward end of a bonding arm is lowered at speed V2, and a ball 41a formed at the lower end part of a wire is brought into contact with the upper surface of a chip 48. When the contact is detected, a motor for oscillating the bonding arm generates a torque f for elevating the capillary tool 42 to brake lowering thereof. Subsequently, the motor generates a torque corresponding to the bonding load F and the ball 41a is pressed against the chip 48.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to wire bonding performed in a process of manufacturing an electronic component, and more particularly to a wire bonding method capable of improving a bonding quality without damaging a chip during wire bonding. .

[0002]

2. Description of the Related Art In the field of manufacturing electronic components, a wire bonding apparatus for electrically connecting a substrate and a chip mounted on the substrate with a wire such as gold is widely used.

Next, a conventional wire bonding apparatus will be described with reference to FIGS. FIG. 16 is a block diagram of a conventional wire bonding apparatus.
6, reference numeral 1 denotes a frame, 2 is a bearing provided at a front portion of the frame 1, and supports a shaft 3; Reference numeral 5 denotes a horn having a base end attached to the rocking body 4 and holding a capillary tool 7 having a wire 6 inserted at the tip thereof, 8 denotes a voice coil type motor for rocking the rocking body 4 and the horn 5, and 9 denotes a motor. An ultrasonic vibrator for applying ultrasonic vibration to the horn 5. Reference numeral 10 denotes a substrate such as a lead frame on which the chip 11 is mounted, 6a denotes a ball formed by electric spark at the lower end of the wire 6, E denotes the rotation amount of the shaft 3 and indirectly indicates the current position of the capillary tool 7. It is an encoder for detecting the position.

A current position counter 20 receives the output of the encoder E and outputs a current position signal of the capillary tool 7 to a computing unit 21. A reference numeral 22 inputs an ultrasonic oscillation signal from a command unit 23 and a contact detection circuit 24. Is an ultrasonic oscillation circuit that vibrates the ultrasonic vibrator 9 weakly when contact detection is to be performed and vibrates strongly when the ball 6a is joined. The contact detection circuit 24 monitors the impedance value of the ultrasonic vibrator 9 against vibration. Here, when the capillary tool 7 is lowered to the bonding surface (the upper surface of the chip 11 or the substrate 10) in a state where a weak vibration is given to the ultrasonic vibrator 9, when the ball 6a is not in contact with the bonding surface, an ultrasonic wave is generated. Since the vibrator 9 and the horn 5 can vibrate freely, the impedance value is low. On the other hand, when the ball 6a comes into contact with the bonding surface, the vibration of the ultrasonic vibrator 9, the horn 5, and the like is suppressed, so that the impedance value sharply increases. Therefore, the contact detection circuit 24 detects the rise in the impedance value and outputs a contact detection signal to the command unit 23. Command unit 23
Outputs a command signal indicating the target position to the computing unit 21. At this time, the computing unit 21 detects a deviation (deviation) of the current position from the target position from the current position signal and the command signal obtained from the current position counter 20, and outputs the deviation to the drive circuit 25.
The drive circuit 25 supplies a drive current corresponding to the deviation to the motor 8.
Output to Of course, if this deviation is large, the drive current applied to the motor 8 will also be large, and the motor 8 will swing the horn 5 in a direction where this deviation becomes zero. On the other hand, during torque control (control of the load pressing the capillary tool 7 against the bonding surface), the command unit 23 outputs a torque signal to the drive circuit 25, and the drive circuit 25 supplies a drive current corresponding to the torque command signal to the motor 8. Apply.

Next, the operation of one cycle of the conventional wire bonding apparatus will be described with reference to FIGS. FIG. 17 is a time chart of the first bonding operation in the conventional wire bonding apparatus. Here, the first bonding operation refers to the operation of the ball 6 at the lower end of the wire 6.
This refers to the operation of bonding a to the chip side, while the operation of bonding the wire 6 to the substrate side is called the second bonding operation. First, at time T1, the capillary tool 7 is at the descent start position, descends at a high speed V1 until reaching a preset search level at a time T2, and descends at a low speed V2 (constant speed) from the search level. The search level is about 200 μm from the upper surface of the chip 11.
m to 300 μm. The command unit 23 outputs an ultrasonic oscillation signal to the ultrasonic oscillation circuit 22 at time T2, and causes the ultrasonic transducer 9 to generate weak vibration for contact detection. Then, the lower end of the ball 6a contacts the upper surface of the chip 11 as the bonding surface at time T3, and at time T4, which is delayed from the time T3 by a small time ΔT, the contact detection circuit 24 detects the contact and detects the contact. When the signal is output, the command unit 23 outputs a torque signal to the drive circuit 25 and causes the drive circuit 25 to apply a drive current corresponding to the bonding load F to the motor 8. Thereafter, the command unit 23 outputs an ultrasonic oscillation command to the ultrasonic oscillation circuit 22 to generate strong vibration for bonding to the ultrasonic vibrator 9, and the ball 6 a
Firmly Then, at time T5, the joining is terminated, and the command unit 23 outputs a command signal for raising the capillary tool 7 at high speed to the drive circuit 25. While repeating the above cycle, a plurality of wires 6 are bonded to one chip 11.

[0006]

Problems to be Solved by the Invention FIG.
17 (b) and (c) respectively show the times T3, T4 and T4 in FIG.
It is explanatory drawing which shows the state of the ball 6a in T5. As shown in FIG. 18 (b), at time T4 when the contact is detected, the movable parts such as the capillary tool 7, the horn 5, and the rocking body 4 move the ball 6a at a speed V3 lower than the speed V2.
It is descending while deforming. In this state, when a drive current corresponding to the bonding load F is applied to the motor 8, a combined force in which the inertial force of the movable portion is superimposed on the bonding load F acts on the ball 6 a and the chip 11 via the capillary tool 7. I do. For this reason, a load exceeding the bonding load F instantaneously acts on the ball 6a and the chip 11, and the ball 6a may be excessively crushed and abnormally spread to cause a bonding failure or damage the chip 11 (FIG. 18). (C)). In particular, in recent years chip 11
Since the number of bonding locations has increased and the spacing between the bonding locations has become narrower with higher functionality and higher integration of the ball 6a, if the ball 6a is too wide as shown in FIG. However, they protrude from the electrodes or come into contact with adjacent balls to cause a short-circuit, which tends to cause bonding failure. Also, the number of chips 11 made of a fragile material such as GaAs has increased, and
However, there is also a problem that there is a possibility that the dies are destroyed.

Further, in the conventional wire bonding method, a bonding load is applied to the bonding surface after detecting that the wire has contacted the bonding surface, so that a delay due to the detection of the contact occurs, and the cycle time is accordingly reduced. There was a problem that it became long.

Accordingly, an object of the present invention is to provide a wire bonding method capable of realizing a high-speed operation without deteriorating the bonding quality.

[0009]

According to the wire bonding method of the present invention, a wire is inserted into a capillary tool held by a bonding arm, the bonding arm is swung by a motor, and a substrate and a chip mounted on the substrate are rotated. A wire bonding method of connecting
Detecting the height of the capillary tool when the wire is in contact with the bonding surface as the height of the bonding surface, and setting a control switching level above the bonding surface based on the height; and Lowering the capillary tool to a control switching level; generating torque in a direction to raise the capillary tool to the motor to brake the lowering of the capillary tool; and bonding the motor to the motor after the capillary tool reaches the control switching level. The method includes a step of lowering the capillary tool by generating a torque according to a load, and pressing a wire against a bonding surface to connect the wire.

[0010]

FIG. 1 is a side view of a wire bonding apparatus according to an embodiment of the present invention. Reference numeral 31 denotes a Y table, and 32 is provided on the upper surface of a Y table 31 so as to be slidable in the Y direction. X table, 33 is Y table 31
, And rotates the ball screw of the ball screw type feed mechanism in the Y table 31 to move the X table 32 in the Y direction. 34 is a support block slidably mounted on the X table 32 in the X direction orthogonal to the Y direction in a horizontal plane, and 35 is an X motor mounted on the X table 32, and a ball screw in the X table 32 The support block 34 is moved in the X direction by rotating the ball screw of the feed mechanism.

Next, the bonding head will be described.
A shaft 36 parallel to the X direction is rotatably supported at the front of the support block 34.
(Bonding arm). E is an encoder for detecting the swing position of the shaft 36, 39 is an ultrasonic transducer mounted on the rear of the horn 37, 40 is a stator 40a fixed on the support block 34, and a rotor 40b is fixed on the box 38. The horn 37 is swung in the direction of arrow N by swinging the box 38 about the shaft 36.

Reference numeral 41 denotes a wire inserted into a capillary tool 42 held at the tip of the horn 37, 43 denotes a tension clamper for applying tension to the wire 41, 44 denotes a wire fixed to the box 38 by a support arm 45, and
Is a torch electrode for forming a ball 41a at the lower end of the wire 41 by generating an electric spark when a high voltage is applied. The torch electrode 46 is fixed to the support block 34 by a fixture (not shown). 47 is a lead frame as a substrate positioned below the capillary tool 42; 47a is an inner lead of the lead frame 47;
Reference numeral 48 denotes a chip mounted on the lead frame 47, and reference numeral 49 denotes a plate that holds the lead frame 47.

FIG. 2 is a block diagram of a wire bonding apparatus according to one embodiment of the present invention. In FIG. 2, 5
0 inputs the A-phase signal and the B-phase signal of the encoder E, determines whether the horn 37 is swinging in the upward or downward direction. For example, a direction discriminating circuit for selectively outputting the falling detection pulse signal b to the reversible counter 51. The direction discriminating circuit 51 counts the rising detection pulse signal a and adds the counted value to the falling detection pulse signal b.
Is counted, the count value is subtracted, and the current count value is output to the interface unit 52 as the current position signal c.

A reference pulse generating circuit 53 generates a reference pulse signal d consisting of a square wave having a sufficiently high constant frequency and outputs the reference pulse signal to a pulse width comparison circuit 54. Reference numeral 54 refers to the reference pulse signal d and a direction discriminating circuit 54. 50, the falling detection pulse signal b output is input, and the threshold N is compared with a value obtained by reducing the pulse width of the falling detection pulse signal b by the pulse width of the reference pulse signal d. This is a pulse width comparison circuit that outputs a contact signal e to the contact detection switch 55 when N exceeds N. The contact detection switch 55 outputs the contact signal e to the interface unit 52 only when the permission signal g is obtained from the interface unit 52.

Next, contact detection means (pulse width comparison circuit 5)
4, the operation of the contact detection switch 55) will be described.
FIG. 10 is an explanatory diagram of contact detection conditions of the wire bonding apparatus according to one embodiment of the present invention. FIG. 10 shows an example in which the threshold value N = 4. The pulse width comparison circuit 54 sets a value obtained by reducing the period B of the falling detection pulse signal b by the constant period A of the reference pulse signal d as a threshold. Compare to the value N,
The contact signal e is output when the threshold value N is reached.

Now, in FIG. 10, the falling detection pulse signal b
The periods B1 to B3 are smaller than the predetermined time 4A obtained by multiplying the period A of the reference pulse signal d by the threshold value N and are substantially constant, indicating that the capillary tool 42 is descending at a substantially constant speed. The cycle B4 is longer than before the cycle B3, indicating that the lowering operation of the capillary tool 42 is decelerating. The cycle B5 is longer than the predetermined time 4A, and the capillary tool 42 almost stops during the cycle B5 (that is, the ball 41a of the wire 41 held at the lower end of the capillary tool 42 contacts the bonding surface). And the period B5
At the time when the predetermined time 4A has elapsed from the rise of the pulse at the pulse width comparison circuit 54, the contact detection signal e
Is output.

In FIG. 2, reference numeral 56 denotes a bonder control unit composed of a CPU or the like, and 57 denotes a ROM.
The control program shown in the flowcharts of FIGS. 7 and 8 is stored in M57, and as shown in FIG.
An operation pattern storage unit 57a storing the operation patterns of FIGS. 11 and 13 and a torque value storage unit 57b storing a torque value corresponding to the bonding load F are provided.

Reference numeral 58 denotes a RAM. As shown in FIG. 5A (see also FIG. 9), the RAM 58 has a height at which the descending speed of the horn 37 is switched from the high speed V1 to the low speed V2 when contact detection is performed. (Normally set 200 to 300 μm above the bonding surface), a control switching level L2 which is a height for switching the control method from the position control to the torque control, and a control switching level L2 for the next bonding location. Correction level ΔL used for
There is provided an area for storing each (constant value).

In FIG. 9, L3 is the height of the lower end of the capillary tool 42 when bonding is completed, and L2 = L
3 + △ L. That is, the control switching level L2 is set at a position above L3 + ΔL from the bonding surface. Incidentally, in this embodiment, the control switching level L2 is set to 50 to 70 μm. In FIG. 5,
The numeral "(1)" in () indicates the height when bonding to the upper surface of the chip 48, and the numeral "2" indicates the height when bonding to the lead frame 47.

In FIG. 2, reference numeral 60 denotes an ultrasonic oscillation circuit for driving the ultrasonic vibrator 39 in response to an ultrasonic oscillation command q from the bonder control unit 56, and 59 denotes a command signal h output from the bonder control unit 56 to the motor 40. (Pulse signal) drive current I
Is a digital servo driver that supplies The bonder controller 56 outputs a pulse signal based on the operation pattern stored in the operation pattern storage 57a to the digital servo driver 59 as a command signal h.

FIG. 3 is a block diagram of a digital servo driver of the wire bonding apparatus according to one embodiment of the present invention. The digital servo driver 59 includes a drive circuit 59a that outputs a drive current I to the motor 40, and an arithmetic unit 59b (deviation detecting means) provided at a stage preceding the drive circuit 59a. The arithmetic unit 59b is connected to the bonder control unit 5
6 and a feedback signal j (pulse signal) transmitted from the encoder E is detected as a droop. When the droop pulse clear signal m is transmitted from the bonder control unit 56, the calculator 59b clears the droop pulse to zero. Drive circuit 59a
Has both a position control function and a torque control function.
Next, the drive circuit 59a will be described with reference to FIG.

A position control circuit 59c for inputting the deviation k output from the calculator 59b and outputting a speed command signal r;
59d is a speed detection circuit which processes the feedback pulse signal j and outputs it as a speed feedback signal s.
e is a speed control circuit that receives a speed command signal r and a speed feedback signal s and outputs a current value necessary for driving the motor 40 as a current command signal u. 59f is a position control method and torque by a control switching signal h. This is a switch for switching between the control method and the control method. When the switch 59f is connected to the speed control circuit 59e, the drive circuit 35
When the position control method is selected and the connection to the bonder control unit 56 is made, the torque control method is selected. The switching of the switch 59f is performed by a control switching signal n from the bonder control unit 56.

A current control circuit 59g outputs a current i based on the current command signal u transmitted from the speed control circuit 59e when the position control system is selected. When the torque control method is selected, a current i corresponding to the torque command signal 1 output from the bonder control unit 56 is output. The current i is supplied to the power amplifier 5
It is amplified at 9h and sent to the motor 40 as a drive current I.

Referring to FIG. 6, the capillary tool 42
The function of braking the descent of the vehicle will be described. H is a level at which the capillary tool 42 is to be braked. Drive circuit 59
It is assumed that the motor 40 is driven and the capillary tool 42 is lowered with a set to the position control function.

As shown in FIG. 6A, the capillary tool 42 descends and is about to pass this level H at a speed V. Here, the fact that the capillary tool 42 has the downward velocity V at the level H means that the target position is set below the level H, and therefore the deviation k between the current position and the target position of the capillary tool 42 Is not zero. Therefore, at the moment when the capillary tool 42 reaches the level H, the accumulated pulse clear signal m is calculated by the arithmetic unit 59b.
When the deviation k is made zero and the transmission of the command signal h is stopped, the level H becomes a new target position. However, since the capillary tool 42 has the velocity V, it goes too far from the level H by a small distance δ, as shown in FIG.

Here, since the target position is at level H,
At the stage where the distance has gone too far as described above, the deviation k corresponding to the small distance δ is newly detected by the calculator 59b. Then, in the position control function, the drive circuit 59a applies the drive current I to the motor 40 so as to make the deviation zero, so that a torque that makes this small distance δ zero is generated in the motor 40. This torque acts to cancel the inertial motion of the movable parts such as the capillary tool 42 and the horn 37.

The above is a phenomenon that occurs in a very short time.
In summary, at the time of position control, if the accumulation pulse clear signal m is transmitted at a certain level at which braking is to be applied and the transmission of the command signal h is stopped, braking of the capillary tool 42 at that level is applied. That you can do it.

Next, an outline of the operation of the wire bonder of the present embodiment will be described with reference to FIGS. 7 and 8 are flowcharts showing the operation of the wire bonding apparatus according to one embodiment of the present invention. FIG.
First, an initialization process is performed (ST1). That is, the bonder control unit 56 initializes the count value of the reversible counter 51 and sets the threshold value N in the pulse width comparison circuit 54.

Next, a high voltage is applied to the torch electrode 46 and the lower end of the wire 41 to generate a spark.
The ball 41a is formed at the lower end of the first (ST2). Next, the bonder control circuit 56 drives the motor 40 to perform a first bonding operation of pressing the ball 41a against the electrode of the chip 48 (ST3). Next, the bonder control unit 56 drives the motor 40, the X motor 35, and the Y motor 33 to move the capillary tool 42 over the inner lead 47a of the lead frame 47 with a predetermined trajectory. 41 is formed to form a loop (ST4).

Next, the tip of the loop is connected to the inner lead 47a.
To perform a second bonding operation (ST5). Then, the wire 41 is clamped by the cut clamper 44, and the cut clamper 44 is raised together with the capillary tool 42,
From the portion joined by the second bonding operation, the wire 41
Is cut (ST6), and the processing of steps 2 to 6 is repeated until the bonding is completed (ST7).

FIG. 8 is a flowchart showing the bonding operation of the wire bonding apparatus according to one embodiment of the present invention. Here, since the flow of the first bonding operation and the flow of the second bonding operation viewed from the bonder control unit 56 are basically the same, only the first bonding operation will be described. First, the bonder control unit 56 sets the control method of the drive circuit 59a to the position control method (S
T11) Then, the bonder control circuit 56 sets the X motor 35, Y
The motor 33 and the motor 40 are driven to move the capillary tool 42 to the lowering start position O (ST12).

Next, it is determined whether or not contact detection is necessary (S
T13). Here, in this embodiment, a new chip 48 is used.
When performing bonding for the first time, a bonding operation that performs contact detection (hereinafter referred to as a search bonding operation)
After the second time, a bonding operation in which contact detection is not performed (hereinafter referred to as a searchless bonding operation) is assumed. The reason for this is that the height of the upper surface of the chip 48 mounted on the lead frame 47 varies for each chip 48 and is inclined. For this reason, the bonder control unit 56 does not accurately recognize the height of the upper surface of the chip on which wire bonding is to be performed for the first time, that is, the height L3 of the lower end of the capillary tool 42 when bonding is completed. It cannot be set correctly. Therefore, in the first bonding operation, wire bonding is performed by a search bonding operation that does not use the control switching level L2.

FIG. 8 shows the search bonding operation.
This will be described with reference to FIGS. In FIG. 11, the horizontal axis indicates time. First, at time T1, the bonder control unit 56
, The capillary tool 42 is lowered at a high speed from the descent start position O to a preset search level L1 (ST14). At time T2, when the capillary tool 42 reaches the search level L1 (ST1
5), the bonder control unit 56 outputs a permission signal g to the contact detection switch 55 via the interface unit 52 so that the contact detection signal e can be detected (ST16). Further, the bonder control unit 56 changes the command signal h so that the lowering speed of the capillary tool 42 is set to a low speed (V2) (ST
17). The speed V2 is a speed that does not damage the chip 48 even if the ball 41a collides with the chip 48.

At time T3, the lower end of the ball 41a comes into contact with the chip 48, and at time T4 when a short time ΔT has elapsed from time T3, when the pulse width comparison circuit 54 issues a contact signal e, the bonder control unit 56 detects that the ball 41a has contacted the bonding surface (ST18). Next, the bonder control unit 56 transmits the accumulation pulse clear signal m to the digital servo driver 59 and stops the transmission of the command signal h to perform the braking process (ST19, ST2).
0).

FIG. 13B shows the state of the ball 41a at time T4 in FIG. The capillary tool 42 is descending while deforming the ball 41a at the speed V3. Here, when the above-described braking process is performed,
A torque f that pushes the capillary tool 42 upward is generated in the motor 40, and the lowering of the capillary tool 42 is braked. Thereby, the capillary tool 42, the horn 37,
The inertia of the box 38 and the rotor 40b is canceled.

After the bonder controller 56 brakes the lowering of the capillary tool 42 by the above-described braking processing, the bonder controller 56 transmits a control switching signal n to the digital servo driver 59 at time T5, and outputs the motor 4 by the drive circuit 59a.
The control method of 0 is switched to torque control (ST21).
Next, the bonder control unit 56 reads the torque command value from the RAM 57, outputs the torque command signal 1, and press-bonds the ball 41a to the chip 48, which is the bonding surface, with a preset torque f (ST22).

Further, an ultrasonic oscillation signal q is output to apply ultrasonic vibration (ST23). Then, at time T6, the bonder controller 56 reads the current position signal c, detects the height L3 of the lower end of the capillary tool 42, calculates the height of the control switching level L2, and calculates the control switching level of the RAM 58. The value of L2 is updated to the newly calculated value this time (ST31). Then, the control method is immediately returned to the position control method (ST32), and the capillary tool 42 is raised at a high speed (ST33).

On the other hand, if it is determined in step 13 that contact detection is unnecessary, a searchless bonding operation shown in FIG. 14 is performed. First, at time T1, the capillary tool 42 at the descent start position O is
When the command pulse signal h is transmitted to 9b, it descends at a high speed at the speed V1 (ST24). Then, the bonder control unit 56 monitors the current position signal c of the reversible counter 51 and, when detecting that the capillary tool 42 has reached the control switching level L2 at time T2 (ST25), digitalizes the accumulated pulse clear signal m. The data is transmitted to the servo driver 59 to perform the above-described braking processing, thereby canceling the inertial force of the movable part such as the horn 37 (ST26, ST27).

After braking the lowering of the capillary tool 42 by the braking process, the bonder controller 56 outputs a control switching signal n to the drive circuit 59a at time T3 (ST28). And immediately, the torque command value storage unit 5
A torque command value corresponding to the bonding load F is read from 7b, and a torque command signal 1 is output to the drive circuit 59a (ST29). The bonding load F is applied until time T6 when the bonding of the wires is completed.

When a predetermined time has elapsed from time T3, the bonder controller 56 sends an ultrasonic oscillation signal q to the ultrasonic oscillation circuit 60.
Is output, and the ultrasonic oscillator 3
9 is operated (ST30). 15 (a), (b),
(C) is an explanatory diagram of the searchless bonding operation, and shows states at times T2, T3, and T4 in FIG. 14, respectively. At time T2, the speed of the capillary tool 42 becomes V
When the control switching level L2 is reached in step 1, the bonder controller 56
Performs a braking process to generate a torque f acting on the motor 42 in a direction to raise the capillary tool 42 to brake the lowering of the capillary tool 42. Then, at time T3, the descending speed of the capillary tool 42 becomes almost zero, and the inertial force of the capillary tool 42, the horn 37, the box 38, and the rotor portion 40b also disappears. From this point, when a torque corresponding to the bonding load F is generated in the motor 40 to lower the capillary tool 42 toward the upper surface of the chip 48, the ball 41a
At 4, the bonding surface (the upper surface of the chip 48) comes into contact, and the torque f generated by the motor 40 is immediately transmitted to the bonding surface as the bonding load F.

As described above, in the searchless bonding operation, the bonding load F is applied from the time when the ball 41a comes into contact with the bonding surface without waiting for the contact detection as in the conventional bonding operation or search bonding operation. In addition, the capillary tool 4 at low speed V2
Since the time for lowering 2 is eliminated, the bonding operation can be performed at a high speed. Immediately before the time T6 when the bonding is completed, the bonder control unit 56 reads the current position signal c, calculates the control switching level L2 similarly to the search bonding operation, and updates the value of the RAM 58 (ST31).

Thereafter, the control method is returned to the position control again, and the capillary tool 42 is raised at a high speed. As described above, also in the case of the searchless bonding operation, the control switching level L2 is updated every one bonding operation. Therefore, even when the chip 48 is inclined with respect to the horizontal plane, the immediately preceding bonding operation is completed. Since the height L3 of the capillary tool 42 at the time is reflected in the control switching level L2 of the next bonding operation, the control switching level L2
Can always be at the correct height.

[0043]

According to the present invention, good bonding quality can be obtained without causing the ball to be crushed and without damaging the chip.

[Brief description of the drawings]

FIG. 1 is a side view of a wire bonding apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram of a wire bonding apparatus according to an embodiment of the present invention.

FIG. 3 is a block diagram of a digital servo driver of the wire bonding apparatus according to the embodiment of the present invention.

FIG. 4 is a block diagram of a driving circuit of the wire bonding apparatus according to the embodiment of the present invention.

5A is a data configuration diagram of a RAM of a wire bonding apparatus according to an embodiment of the present invention; FIG. 5B is a data configuration diagram of a ROM of the wire bonding apparatus according to an embodiment of the present invention;

FIG. 6A is an explanatory diagram of a breaking process of the wire bonding apparatus according to one embodiment of the present invention; FIG. 6B is an explanatory diagram of a breaking process of the wire bonding device according to one embodiment of the present invention;

FIG. 7 is a flowchart showing the operation of the wire bonding apparatus according to one embodiment of the present invention.

FIG. 8 is a flowchart showing a bonding operation of the wire bonding apparatus according to one embodiment of the present invention.

FIG. 9 is an explanatory diagram of a control switching level L2 of the wire bonding apparatus according to the embodiment of the present invention.

FIG. 10 is an explanatory diagram of a contact detection condition of the wire bonding apparatus according to one embodiment of the present invention.

FIG. 11 is an explanatory diagram of a contact detection condition of the wire bonding apparatus according to one embodiment of the present invention.

FIG. 12 is a time chart of a search bonding operation of the wire bonding apparatus according to one embodiment of the present invention;

13A is a diagram illustrating a search bonding operation of the wire bonding apparatus according to one embodiment of the present invention; FIG. 13B is a diagram illustrating a search bonding operation of the wire bonding device according to one embodiment of the present invention; Explanatory drawing of the search bonding operation | movement of the wire bonding apparatus in one Embodiment of this invention

FIG. 14 is a time chart of a searchless bonding operation of the wire bonding apparatus according to an embodiment of the present invention.

15A is a diagram illustrating a searchless bonding operation of the wire bonding apparatus according to one embodiment of the present invention; FIG. 15B is a diagram illustrating a searchless bonding operation of the wire bonding apparatus according to one embodiment of the present invention; FIG. 4 is an explanatory diagram of a searchless bonding operation of the wire bonding apparatus according to one embodiment of the present invention.

FIG. 16 is a block diagram of a conventional wire bonding apparatus.

FIG. 17 shows a first example of a conventional wire bonding apparatus.
Time chart of bonding operation

18A is a diagram illustrating a bonding operation of a conventional wire bonding apparatus. FIG. 18B is a diagram illustrating a bonding operation of a conventional wire bonding device. FIG. 18C is a diagram illustrating a bonding operation of a conventional wire bonding device.

[Explanation of symbols]

 37 Horn 40 Motor 41 Wire 41a Ball 42 Capillary tool 47 Lead frame 48 Chip

Claims (1)

[Claims] 1. A wire bonding method for inserting a wire through a capillary tool held by a bonding arm, swinging the bonding arm with a motor, and connecting a substrate and a chip mounted on the substrate by a wire, Detecting the height of the capillary tool when the wire is in contact with the bonding surface as the height of the bonding surface, and setting a control switching level above the bonding surface based on the height; and Lowering the capillary tool to a control switching level; generating torque in a direction to raise the capillary tool in the motor to brake the lowering of the capillary tool; bonding to the motor after the capillary tool reaches the control switching level. A torque corresponding to the load is generated to A wire bonding method comprising a step of lowering a pillar tool and pressing a wire against a bonding surface to connect the wire.