KR102469435B1 - Substrate treating method and apparatus for attaching solderbals on predetermined pattern of places on substrate - Google Patents

Abstract

The present invention relates to a substrate processing method and apparatus for attaching solder balls to a substrate in a predetermined pattern, comprising: a flux supply step of supplying flux to a predetermined position according to a pattern of a substrate; a solder ball pickup step of picking up and holding solder balls in the solder ball pickup unit of a solder ball tool having solder ball pickup units distributed according to the pattern; a mask positioning step of positioning a guide mask having through holes formed according to the pattern above the substrate; a solder ball tool positioning step of locating the solder ball tool on an upper side of the guide mask so that the through hole of the guide mask and the solder ball pick-up part are aligned; a solder ball attaching step of removing suction pressure applied to the solder ball pick-up unit to drop and attach the solder ball from the solder ball tool to a predetermined position according to the pattern on the substrate; consists of including Through this, the present invention can accurately attach the solder ball to the connection position of the predetermined pattern even if warpage of the board occurs, and contamination of the solder ball tool is fundamentally eliminated, improving process efficiency and accuracy at the same time. effect can be obtained.

Description

A substrate processing method for attaching solder balls to a substrate in a predetermined pattern and a substrate processing apparatus used therein

The present invention relates to a method of attaching solder balls to a substrate in a predetermined pattern and to a substrate processing apparatus used therein, and more particularly, to a substrate that is thin enough to be easily bent and solder balls to be placed in an accurate position even if they are more densely arranged. It relates to a substrate processing method and apparatus for attaching solder balls.

As the degree of integration of semiconductor packages increases, instead of electrically connecting the upper and lower chips using wires, fine solder balls distributed in the same pattern on the upper and lower chips are used to connect the upper and lower chips. A stacking process for laminating is widely applied.

That is, as shown in FIG. 1, a plurality of unit chips U1 are formed on the first substrate S1 in a predetermined pattern, and as shown in FIG. 2, the substrate of each unit chip U1. Elements K such as a logic circuit and a memory are mounted thereon. In addition, although the unit chip U1 itself can be used as a semiconductor device, a highly integrated semiconductor device is manufactured by stacking chips in a vertical direction. To this end, each unit chip U1 is provided with a plurality of connection positions Bx electrically connecting the top and bottom stacked chips.

And, as shown in FIG. 3, in a state where a predetermined amount of flux 55 is applied to the end of the flux pin 51 using the flux tool 50 at the predetermined connection position Bx of the substrate S1. As shown in FIG. 4, the solder ball 70 picked up by the solder ball tool 60 is brought close to the board S1 (67) and the pressure in the inner space (60c) is adjusted. is released and seated on the flux 55 of the substrate S1, and the solder ball 70 is formed into a bump shape through a reflow process.

However, in recent years, as the trend of miniaturization of semiconductor packages has become more severe, the distance between the connection positions Bx where the solder balls are seated has become smaller, the diameter of the solder balls has become smaller, and the substrate ( The thickness of S1) also tends to become thinner.

Accordingly, when a slight twisting deformation occurs in the substrate S1 on which the plurality of unit chips U1 are connected, the connection position Bx at the other end of one connection position Bx as a reference indicates that the substrate is flat. The premise distance and deviation will be created. That is, based on FIG. 4, the distance (x) of the solder balls 70 picked up by the solder ball tool 60 is set equal to the distance between the connection positions (Bx) when the substrate (S1) is in a flat state (S1p). However, when fine warpage occurs in the substrate S1, the distance x' between the connection positions Bx is further reduced. Therefore, if one of the solder balls picked up by the solder ball tool 60 is aligned on the basis of aligning any one connection position, the solder ball tool 60 picks up the other connection position at a distance from the connection position on the alignment basis. A deviation (c) from the solder ball occurs, causing a problem of not being accurately attached to the connection position (Bx) of the board (S1).

In addition to this, when the elements K are first mounted on the board S1 before the solder ball 70 is attached to the board S1, the solder ball 70 protrudes downward from the bottom surface of the solder ball tool 60. When the length 70d is smaller than the height h of the mounted element K, the position of the solder ball may be displaced in the process of dropping the solder ball 70 from the solder ball tool 60.

And, when the length 70d of the downward protrusion of the solder ball 70 from the bottom surface of the solder ball tool 60 is smaller than the height h of the mounted element K, the bottom surface of the solder ball tool 60 is placed on the substrate ( In the process of approaching S1), the bottom surface of the solder ball tool is contaminated by contact with the flux 55 already applied to the substrate S1. If the bottom surface of the solder ball tool is partially contaminated with the flux 55, an error occurs in the solder ball attach process in the next process, causing problems such as process delay.

Therefore, in spite of the tendency of thin, thin and short semiconductor packages, contamination of the solder ball tool is prevented and despite the bending deformation of the board, the solder balls 70 are accurately attached to the connection positions Bx disposed at close intervals. The need is desperately needed.

In order to solve the above problems, an object of the present invention is to provide a substrate processing method and apparatus for accurately locating solder balls at connection positions of a predetermined pattern even when torsional deformation is caused due to a thin substrate.

That is, the present invention corrects the distortion of the board in the process of attaching the solder balls, so that even if the size of the solder balls is miniaturized and the connection positions are densely distributed, the solder balls are accurately attached to the predetermined connection positions of the board. do.

In addition, an object of the present invention is to fundamentally suppress contamination of a solder ball tool for carrying and attaching solder balls in a process of attaching solder balls to connection positions of a predetermined pattern on a board.

In order to achieve the above object, the present invention provides a method for supplying solder balls in a predetermined pattern on a substrate, comprising: a flux supply step of supplying flux to a predetermined position according to the pattern on the substrate; a solder ball pickup step of picking up and holding solder balls in the solder ball pickup unit of a solder ball tool having solder ball pickup units distributed according to the pattern; a mask positioning step of positioning a guide mask having through holes formed according to the pattern above the substrate; a solder ball tool positioning step of locating the solder ball tool on an upper side of the guide mask so that the through hole of the guide mask and the solder ball pick-up part are aligned; a solder ball attaching step of removing suction pressure applied to the solder ball pick-up unit to drop and attach the solder ball from the solder ball tool to a predetermined position according to the pattern on the substrate; It provides a substrate processing method characterized in that configured to include.

In the process of attaching the solder balls to the connection positions distributed according to the predetermined pattern of the board, the solder ball tool is attached to the board by interposing a guide mask having through-holes aligned with the connection position between the solder ball tool and the board. This is to prevent contamination of the solder ball tool even when the solder ball is attached in close proximity.

In addition, since the path in which the solder ball falls from the solder ball tool to the predetermined connection position is guided by the through hole of the guide mask, it is possible to ensure that the solder ball is attached to the correct position even if the solder ball tool is spaced apart from the substrate.

Above all, in the mask positioning step, by placing the guide mask supported on the substrate, by inducing the substrate to be unfolded by the weight of the guide mask, even if the thickness of the substrate is thin and the material easily warped, the substrate Since the solder ball attach process is performed in this flatly spread state, even if the connection positions are densely distributed and the solder balls are formed in a fine size, the effect of accurately attaching the solder balls to the predetermined connection positions can be obtained.

To this end, the guide mask may be formed to a thickness greater than the diameter of the solder ball. Alternatively, the guide mask may be formed to have a self-weight of a size that allows a bent portion of the substrate to be unfolded while being supported on the substrate.

Furthermore, in a state in which the guide mask is supported on the substrate, pressing the guide mask downward to unfold the bent portion of the substrate; It may be further included.

In addition, the guide mask protrudes downward in an area where the through hole is not formed to form a protruding support that contacts the substrate, and the flux supplied to the substrate is spaced apart from the guide mask, so that the flux already applied to the guide mask contamination can be prevented.

The solder ball pickup step may include applying a suction pressure to the solder ball pickup unit to pick up the solder ball, and the solder ball attaching step may include attaching the solder ball to the substrate by removing the suction pressure from the solder ball pickup unit.

In the solder ball attaching step, vibrating the solder ball tool is performed in parallel, thereby minimizing that the solder balls from the solder ball tool remain attached due to static electricity, and allowing all the solder balls to be moved to the substrate and attached.

Here, since the solder ball tool vibrates in the vertical direction, it is possible to prevent the solder ball from being twisted to an incorrect position even when the solder ball tool vibrates.

On the other hand, according to another field of the invention, the present invention is a substrate processing apparatus for supplying solder balls in a predetermined pattern on a substrate, comprising: a flux supply tool for supplying flux to a predetermined position according to the pattern of the substrate; A solder ball pickup unit distributed according to the pattern is provided, the solder balls are picked up and held by the solder ball pickup unit, and the solder balls held while the solder ball pickup unit is positioned on the flux are dropped and attached to the substrate. tools; Before attaching the solder ball from the solder ball tool to a predetermined position of the substrate, a guide mask having a through hole formed according to the pattern and positioned on the upper side of the substrate; It provides a substrate processing apparatus characterized in that configured to include.

The term 'flux' used in this specification and claims collectively refers to materials that are melted by heat in order to combine solder balls, and not only non-conductive materials, but also electrically conductive materials (for example, solder ball paste ) is defined as including

The term 'negative pressure' or 'suction pressure' as used in this specification and claims refers to a pressure lower than atmospheric pressure and includes a vacuum state.

As described above, the present invention, in the process of attaching solder balls to connection positions distributed according to a predetermined pattern of the substrate, a guide mask having through-holes aligned with the connection position is interposed between the solder ball tool and the substrate Accordingly, even if the solder ball tool attaches the solder ball in close proximity to the substrate, contamination of the solder ball tool can be prevented.

In addition, the present invention has the effect of ensuring that the solder ball is attached to the correct position even if the solder ball tool is spaced apart from the substrate, since the path in which the solder ball falls from the solder ball tool to the predetermined connection position is guided by the through hole of the guide mask. can be obtained.

Above all, the present invention induces the substrate to be unfolded by the weight of the guide mask or an additional load by placing the guide mask to be supported on the substrate, even if distortion has already occurred in the substrate, the guide mask Since the solder ball attach process is performed in a state where the board is spread flat through the board, even if the connection positions are densely distributed and the solder balls are formed in a fine size, the effect of accurately attaching the solder balls to the predetermined connection positions can be obtained.

That is, the present invention can accurately attach solder balls to the connection positions of a predetermined pattern even if warpage of the board occurs, and the contamination of the solder ball tool is fundamentally eliminated, thereby improving process efficiency and accuracy at the same time. can be obtained.

1 is a perspective view showing a substrate on which unit chips are arranged vertically and horizontally;
Figure 2 is an enlarged view of the unit chip of Figure 1 removed;
Figure 3 is a cross-sectional view taken along the cutting line II-II of Figure 2, showing a configuration for supplying flux to the connection position of the substrate;
Figure 4 is a cross-sectional view taken along the cutting line II-II of Figure 2, showing a configuration for attaching solder balls to the connection position of the board;
5 is a flowchart sequentially showing a substrate processing method according to an embodiment of the present invention;
6 is a view showing a configuration of applying flux to connection positions according to a predetermined pattern of a substrate;
7 is a diagram showing a configuration for gripping a solder ball in a pickup part of a solder ball tool;
8 is a diagram showing a configuration for positioning a guide mask on the upper surface of a substrate;
Figure 9 is an enlarged view showing part 'A' of Figure 8;
10 is a view showing a configuration for introducing an additional load to the guide mask of FIG. 8;
11 is a view showing a configuration in which the solder ball tool is moved and aligned to the upper side of the guide mask;
12 is a view showing a configuration for attaching a solder ball to a substrate from a solder ball tool;
13 is a diagram showing a configuration for moving a substrate to which solder balls are attached to a reflow process.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The substrate processing apparatus 100 according to an embodiment of the present invention is used during a process for manufacturing a semiconductor package, and supplies flux to a predetermined connection position Bx according to a predetermined pattern of a substrate S1. A solder ball tool 120 having a flux supply tool 110 and a solder ball pick-up unit 122 distributed according to the pattern to supply solder balls 70 to a predetermined connection position Bx of the board S1, and solder balls Prior to attaching the solder ball 70 from the tool 120 to the predetermined position Bx of the substrate S1, a through hole 131 is formed according to the pattern and the guide mask is positioned above the substrate S1. (130).

As shown in FIGS. 1 and 2 , the substrate S1 is formed by connecting a plurality of unit chips U1 used to manufacture a semiconductor package vertically and horizontally, and each unit chip U1 has a predetermined pattern. Connection positions (Bx) distributed according to are formed. Although the configuration in which the element K is previously mounted on the unit chip U1 is illustrated in the drawing, the element K may be mounted after the solder ball 70 is attached to the substrate S1.

In addition, the pattern shape of the connection position Bx may be formed in the form illustrated in the drawing, but is not limited thereto and may be formed in various other forms. 6 to 13 show only a portion of the substrate S1 of FIG. 1 for convenience in order to facilitate understanding of the present invention. In the drawing showing the substrate S1, a portion marked as U1 indicates an area occupied by the unit chip U1.

The solder balls 70 attached to the substrate S1 are used in a miniature form having a diameter of approximately 300 μm, but smaller solder balls 70 having a diameter of 50 to 250 μm may be applied.

The flux supply tool 110 can be moved (110d) in the horizontal and vertical directions by various known means, and the flux pin 111 aligned with the connection position (Bx) according to the pattern of the substrate (S1) It is formed protruding downward. Therefore, by slightly submerging the flux pin 111 in a container (not shown) containing the flux, an appropriate amount of flux 50 is buried in the flux pin 111 at the bottom of the flux pin 111, and the flux With the tool 110 and the substrate S1 aligned, the flux tool 110 is moved downward so that the flux pin 111 slightly contacts the substrate S1, thereby connecting the substrate S1 according to a predetermined pattern. A predetermined amount of flux 50 may be supplied to the position Bx in a dotting method.

In the drawing, a configuration of supplying the flux 50 to the connection position Bx of the substrate S1 by using the flux tool 110 is exemplified, but the present invention is not limited thereto, and the element K on the substrate S1 ) is not mounted, the flux 50 may be supplied to the connection position Bx by a method of printing the substrate S1 with the flux 50 by a printer.

As shown in FIG. 8, the guide mask 130 has a through hole 131 aligned with the connection position Bx according to the pattern of the substrate S1, so that the solder balls 70 are formed in the solder ball attach process. It forms a falling path.

The guide mask 130 may be installed in an airborne form separated from the substrate S1 to guide the falling path of the solder balls 70, but according to a preferred embodiment of the present invention, shown in FIGS. 8 and 9 As described above, it is preferable that the lower surface of the guide mask 130 is mounted in a form supported in close contact with the substrate S1. Through this, even if the board S1 is thin and warp deformation occurs, the weight of the guide mask 130 induces the warp deformation to spread flat, so that a part of the solder ball 70 is connected by the board S1 warp deformation. It is possible to obtain an effect of preventing an attach error from occurring due to not being accurately aligned with the position Bx.

Here, the diameter 131a of the through hole 131 of the guide mask 130 guides the falling path of the solder ball 70, so it is formed larger than the diameter of the solder ball 70, but the flux applied to the substrate S1 It may not be formed larger than the diameter (55a) or width of (55). To this end, the entire bottom surface of the guide mask 130 is configured to be in close contact with the upper surface of the substrate S1, rather than the space between the connection positions Bx of each unit chip U1 (ie, the boundary area between unit chips, A protruding support 134 protruding downward may be formed only on a portion of the guide mask 130 aligned with Sx.

Through this, since a gap e is provided between the guide mask 130 and the applied flux 55 in the area where the connection locations Bx are distributed and spaced apart in the vertical direction, the flux applied to the substrate in the solder ball attach process Since 55 can be prevented from being contaminated by the guide mask 130 or fluctuating the amount of flux on the substrate, it is possible to obtain the advantage of being reliable and constant even if the solder ball attach process is repeated. In addition, since the guide mask 130 can be disposed at a sufficiently high distance from the upper surface of the substrate by the protruding support 134, even if the element K is already mounted in the center of the unit chip U1, the solder ball attach process can be done smoothly.

Further, the protruding support 134 is spaced apart (134x) in the lateral direction even between regions (Sx) forming the unit chip U1 so as to be spaced apart from the flux 55 already applied to the substrate S1 in the horizontal direction as well. It is preferable to be formed so that it protrudes downward only at the position where it is.

On the other hand, the guide mask 130 is mounted on the substrate S1 so that the distortion deformation of the substrate S1 is spread flat by the guide mask 130 supported and mounted on the substrate S1. It is preferable to be formed to have a self-weight of a size that allows the bent portion to unfold (ss) by the torsional deformation of the. For example, the guide mask 130 may be formed of a metal material and have a thickness greater than the diameter of the solder ball 70 .

Alternatively, according to another embodiment of the present invention, when the self-weight of the guide mask 130 is not large enough, the guide mask 130 is lowered in a state where the guide mask 130 is supported on the substrate S1. A pressing means 140 for pressing may be provided. Here, as shown in FIG. 10, the pressing means 140 may be formed as a weight placed on the guide mask 130, or may be a means for applying force downward. And, although the force for pressing the guide mask 130 downward by the pressing means 140 may be introduced at the same time, as shown in FIG. 10, a predetermined load is introduced at a position close to one side of the substrate S1 ( 140d1), and sequentially introduce loads (140d2, 140d3, 140d4, 140d5, 140d6) to positions adjacent to the other side of the substrate S1, thereby moving the bent portion in a wavy shape (ss1) while moving the substrate S1 ) can be flattened.

As shown in FIG. 11, in the solder ball tool 120, the pick-up unit 122 that suctions and holds the solder balls 70 one by one has the same arrangement of connection positions Bx according to the pattern shape of the substrate S1. It is provided on the bottom surface and is configured to adjust the pressure of the inner space 120c by the pressure control unit P.

In addition, a pin block 125 having a plurality of pressing pins 125a formed thereon is installed in the inner space 120c of the solder ball tool 120 in the same manner as the arrangement of the pattern, and can be moved vertically by the driving unit M. be installed In addition, the solder ball tool 120 is installed to be movable in the horizontal and vertical directions by means of a transfer unit 120M having various well-known configurations, and vibrate (120v) in the vertical direction.

Hereinafter, a substrate processing method (S100) using the substrate processing apparatus 100 according to an embodiment of the present invention configured as described above will be described in detail.

Step 1 : As shown in FIGS. 1 and 2, a substrate S1 to which unit chips U1 are vertically and horizontally connected is prepared (S110). Here, the element K constituting the semiconductor package may be previously mounted on the substrate S1 or, although not shown in the drawings, the element K may not be mounted.

The substrate S1 is mounted on a cradle 90 where the solder ball attach process is to be performed, and the cradle 90 has an alignment sensor 95 for detecting the alignment of the substrate S1 and the components used in the subsequent process. may be provided. In the embodiment shown in the drawing, the substrate S1 is mounted in a predetermined position on the cradle 90, and in some cases, a plurality of suction holes are provided in the cradle 90 to fix the position of the substrate S1, and the substrate ( The position of S1) may be suction fixed.

Step 2 : Then, as shown in FIG. 6, flux 55 is dotted at the connection position Bx according to the pattern of the substrate S1 (S120). To this end, the flux tool 110 having the flux pins 111 distributed according to the pattern is moved (110d), the flux pins 111 are slightly submerged in the flux 55, and then pulled out, the flux pins ( 111) so that the flux 55 forms on the bottom.

Here, the control of the amount of flux 55 is determined by the cross-sectional shape and size of the flux pin 111 and the depth to which the flux pin 111 is submerged.

Then, when the flux 55 is formed on the lower end of the flux pin 111 by a predetermined amount, the flux tool 110 is moved and, as shown in FIG. 6, by the alignment sensor 95 of the holder 90 By sensing the sensing unit 116 of the flux tool 110, the flux pin 111 of the flux tool 110 is aligned with the connection position Bx of the substrate S1. Then, by raising the flux tool 110 immediately after moving the flux tool 110 downward so that the flux pin 111 slightly contacts the connection position Bx of the substrate S1, the connection of the substrate S1 A predetermined amount of flux 55 is dotted for each position Bx.

Step 3 : Then, as shown in FIG. 7, the solder ball tool 120 is moved (120d1) to the solder ball container 170 by the transfer unit 120M, and the solder ball tool 120 is moved by the pressure adjusting unit P. By applying negative pressure (v) to the inner space 120c of ), the solder balls 70 are suctioned and picked up one by one by the pick-up unit 122 of the solder ball tool 120.

At this time, the pin block 125 moves upward (125d1) so that the solder ball 70 is not interfered with the pressing pin 125a of the pin block 125 in the process of being sucked and held by the pick-up unit 122. .

In addition, the solder ball container 170 is excited in the vertical direction 170d by the driving unit M', so that the solder balls 70 are sucked into the pickup unit 122 of the solder ball tool 120 one by one and picked up in a shorter time. can be done during

Step 4 : Apart from performing step 3, the guide mask 130 through which the through hole 131 aligned with the connection position Bm of the substrate S1 is formed is placed on the upper side of the substrate S1 (S130 ).

At this time, the sensor 136 of the guide mask 130 is detected by the alignment sensor 95 formed on the holder 90, and the through hole 131 of the guide mask 130 is connected to the substrate S1. Make it aligned with (Bx). In addition, by placing the guide mask S1 on the upper side of the substrate, the solder ball 70 to be attached to the through hole 131 of the guide mask S1 reliably guides the solder ball 70 to the connection position Bx of the substrate. will be able to do

At this time, the guide mask 130 may be suspended in the air in a non-contact state with the substrate S1 to guide the supply of the solder balls 70 by falling to the connection position Bm of the substrate S1. According to a preferred embodiment of the present invention, as shown in Figure 8, the guide mask 130 is preferably installed to be mounted in a form supported by the substrate (S1). Through this, even when the thin substrate S1 is slightly warped due to the weight of the guide mask 130, the substrate S1 is spread flat and the interval between the pattern-shaped connection positions Bx is increased. All at scheduled intervals.

And, even when the guide mask 130 is supported on the substrate S1 while being in contact with it, as the protruding support 134 protrudes downward between the areas Sx forming the unit chip U1, Even if the through hole 131 of the guide mask 130 is smaller than the width 55a of the flux 55 applied to the substrate S1, there is a gap between the bottom surface of the guide mask 130 and the flux 55. (e) can prevent the bottom surface of the guide mask 130 from being contaminated by the flux 55. In addition, even if the elements K are already mounted in the middle of the unit chip U1, since the lower surface of the guide mask 130 is vertically spaced apart from the upper surface of the substrate S1 by a sufficient space, the mounted A space capable of accommodating the element K may be provided.

On the other hand, when the thickness of the guide mask 130 is very thin or formed of a light material, the effect of spreading the warpage flat by pressing the substrate S1 downward is lowered. In this case, as shown in FIG. 10 , the distortion of the substrate S1 can be corrected by introducing a weight or a downward pressing force as the pressing means 40 to the guide mask 130 .

At this time, although placing or introducing the pressing means 140 on the guide mask 130 may be performed at once, placing or introducing the pressing means 140 on the portion Sx located outside the connection area Bx It may be performed while moving sequentially (140d1 → 140d2 → 140d3 → 140d4 → 140d5 → 140d6) from the part Sx close to one side of the substrate S1 to the part close to the other side of the substrate with a time difference. Through this, when distortion occurs in the substrate S1 in a bent form, the substrate S1 may be corrected in a flat posture while moving the bent portion from one side to the other side.

Step 5 : Then, the solder ball tool 120 that picked up the solder balls 70 in step 3 is moved (120d2) to the upper side of the board S1, and as shown in FIG. 11, the solder ball 70 and the board The connection positions Bm are aligned (S140).

Even at this time, the alignment sensor 95 installed on the cradle 90 detects the sensing unit 128 of the solder ball tool 120, and the solder balls 70 picked up by the solder ball tool 120 are located on the substrate S1. It is aligned with the connection position (Bx).

Step 6 : Then, as shown in FIG. 12, the negative pressure v introduced into the inner space 120c of the solder ball tool 120 is removed, so that the solder balls 70 pass through the through holes of the guide mask 130. It falls to the connection position (Bx) of the board (S1) through (131) and is attached to the flux 55 at the connection position (Bx) (S150).

Here, even if the position of the flux 55 is slightly different from the connection position (Bx), the flux 55 is applied over a somewhat larger area than the connection position (Bx), and in step 4, the upper side of the substrate (S1) Since the solder ball 70 is attached to the correct connection position in a state where the posture is corrected flat by the mounted guide mask 130, the solder ball 70 finally attached to the board S1 is at the connection position Bx. It becomes an attached state exactly.

At this time, when the diameter of the solder ball 70 is very small, such as 50 - 300 μm, there is a case where the solder ball 70 remains attached to the recessed pickup part 122 of the solder ball tool 120 by electrostatic force. often occurs In order to release the attached state due to the electrostatic force, the lightweight solder balls 70 are separated from the solder ball pick-up unit 122 by being excited (120v) in the vertical direction by the transfer unit 120M of the solder ball tool 120 to separate the substrate. The reliability of dropping in (S1) can be further increased.

When the pressing pin block 125 is provided inside the solder ball tool 120, the pin block 125 moves downward while removing the negative pressure v introduced into the inner space 120c of the solder ball tool 120. (125d2), the pressing pins 125a of the pin block 125 physically push each solder ball 70 away from the pick-up unit 122 to forcibly separate them, and the solder balls 70 fall downward to the substrate. It may work as attached to (S1). In addition, while removing the negative pressure (v) from the pressure adjusting unit (P), the positive pressure (px) is introduced into the inner space (120c), and the solder ball is pushed out by the air blowing method by pneumatic pressure to the pick-up part of the solder ball tool 120. can be clearly separated from

In this way, during the process of attaching the solder balls 70 from the solder ball tool 120 to the substrate S1, since the solder ball tool 120 does not directly contact the flux 55 by the guide mask 130, the solder ball In the attach process, it is possible to solve the conventional problem of contamination by the flux 55 on the lower surface of the solder ball tool 120 (in particular, the solder ball pick-up unit 122).

Step 7 : Then, as shown in FIG. 12, the solder ball tool 120 moves upward (120d3) and then moves to the solder ball storage container 170, as shown in FIG. 7, preparing step 3 in advance. are transported to

Then, the guide mask 130 moves upward and waits until the substrate S1 of the next process is supplied to the holder 90 .

Then, the substrate S1 to which the solder balls 70 are attached is inspected by an inspection vision (not shown) to see if all the solder balls 70 are correctly attached to the pattern-shaped connection positions Bx, and the ball-shaped The solder balls are transferred (88) to a reflow process unit for forming semicircular bumps.

The substrate processing method according to an embodiment of the present invention configured as described above can accurately attach the solder ball 70 to the connection position of the predetermined pattern even if warpage of the substrate occurs, and each unit chip Even when the element (K) is already mounted on (U1), the solder ball attach process can be smoothly performed, and contamination of the solder ball tool 120 and the guide mask 130 is prevented, which is advantageous in improving process efficiency and accuracy at the same time. effect can be obtained.

In the above, preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited only to these specific embodiments, and can be appropriately changed within the scope described in the claims.

100: substrate processing device 110: flux tool
120: solder ball tool 130: guide mask
55: flux 70: solder ball
U1: unit chip S1: substrate

Claims (22)

A substrate processing method related to supplying solder balls in a predetermined pattern on a substrate,
a flux supply step of supplying flux to a predetermined location according to the pattern of the substrate;
a solder ball pickup step of picking up and holding solder balls in the solder ball pickup unit of a solder ball tool having solder ball pickup units distributed according to the pattern;
a mask positioning step of positioning a guide mask having through-holes formed according to the pattern on an upper side of the substrate and supporting the guide mask on the substrate;
a solder ball tool positioning step of locating the solder ball tool on an upper side of the guide mask so that the through hole of the guide mask and the solder ball pick-up part are aligned;
a solder ball attaching step of removing suction pressure applied to the solder ball pick-up unit to drop and attach the solder ball from the solder ball tool to a predetermined position according to the pattern on the substrate;
The method of claim 1 , wherein the guide mask has a weight such that a bent portion of the substrate is unfolded in a state in which the guide mask is supported on the substrate.
A substrate processing method related to supplying solder balls in a predetermined pattern on a substrate,
a flux supply step of supplying flux to a predetermined location according to the pattern of the substrate;
a solder ball pickup step of picking up and holding solder balls in the solder ball pickup unit of a solder ball tool having solder ball pickup units distributed according to the pattern;
a mask positioning step of positioning a guide mask having through-holes formed according to the pattern on an upper side of the substrate and supporting the guide mask on the substrate;
spreading the bent portion of the substrate by pressing the guide mask downward while the guide mask is supported on the substrate;
a solder ball tool positioning step of locating the solder ball tool on an upper side of the guide mask so that the through hole of the guide mask and the solder ball pick-up part are aligned;
a solder ball attaching step of removing suction pressure applied to the solder ball pick-up unit to drop and attach the solder ball from the solder ball tool to a predetermined position according to the pattern on the substrate;
A substrate processing method characterized in that configured to include.
According to claim 1 or 2,
The guide mask is a substrate processing method, characterized in that formed to a thickness thicker than the diameter of the solder ball.
delete delete According to claim 1 or 2,
The guide mask protrudes downward in an area where the through hole is not formed to form a protruding support in contact with the substrate, so that the flux supplied to the substrate is spaced apart from the guide mask.
According to claim 1 or 2,
The solder ball pickup step applies suction pressure to the solder ball pickup unit to pick up solder balls, and the solder ball attachment step removes the suction pressure to the solder ball pickup unit to attach the solder balls to the substrate. Way.
According to claim 7,
The solder ball attaching step is a substrate processing method, characterized in that in parallel with vibrating the solder ball tool.
According to claim 8,
The solder ball tool is a substrate processing method, characterized in that for vibrating in the vertical direction.
A substrate processing apparatus for supplying solder balls in a predetermined pattern on a substrate,
a flux supply tool for supplying flux to predetermined connection positions according to the pattern of the substrate;
A solder ball pickup unit distributed according to the pattern is provided, the solder balls are picked up and held by the solder ball pickup unit, and the solder balls held while the solder ball pickup unit is positioned on the flux are dropped and attached to the substrate. tools;
Before attaching a solder ball from the solder ball tool to a predetermined connection position of the board, a through hole is formed according to the pattern and mounted so as to be supported on the board so as to be located on the upper side of the board. a guide mask having a self-weight of a size that allows the bent portion of the substrate to be unfolded in the state;
A substrate processing apparatus comprising a.
According to claim 10,
The guide mask is a substrate processing apparatus, characterized in that formed to a thickness thicker than the diameter of the solder ball.
delete delete A substrate processing apparatus for supplying solder balls in a predetermined pattern on a substrate,
a flux supply tool for supplying flux to predetermined connection positions according to the pattern of the substrate;
A solder ball pickup unit distributed according to the pattern is provided, the solder balls are picked up and held by the solder ball pickup unit, and the solder balls held while the solder ball pickup unit is positioned on the flux are dropped and attached to the substrate. tools;
a guide mask supported and mounted on the substrate so that the through hole is formed according to the pattern and located on the upper side of the substrate before attaching the solder ball from the solder ball tool to a predetermined connection position of the substrate;
a pressing means for downwardly pressing the guide mask while the guide mask is supported on the substrate;
A substrate processing apparatus comprising a.
According to claim 14,
The substrate processing apparatus, characterized in that the pressing means is a weight placed on the guide mask.
According to claim 14,
The substrate processing apparatus according to claim 1 , wherein the pressing means sequentially presses the guide mask downward while moving from one side of the substrate to the other side.
According to any one of claims 10 or 11 or 14 to 16,
The guide mask has a protruding support protruding downward in an area where the through hole is not formed and contacting the substrate, so that the flux supplied to the substrate while the guide mask is mounted on the substrate is connected to the guide mask in a vertical direction. A substrate processing apparatus characterized in that spaced apart.
According to claim 17,
The substrate processing apparatus, characterized in that the substrate is formed in a form in which a plurality of unit chips are vertically and horizontally connected, and the protruding support is formed in a boundary region of the unit chips.
According to any one of claims 10 or 11 or 14 to 16,
The solder ball tool applies suction pressure to the solder ball pickup unit to pick up solder balls, and then removes the suction pressure to the solder ball pickup unit to attach the solder balls to a predetermined position according to the pattern of the substrate. Substrate processing device.
According to claim 19,
The substrate processing apparatus further comprising a vibrating means for vibrating the solder ball tool in the process of dropping and attaching the solder ball from the solder ball tool.
21. The method of claim 20,
The solder ball tool is a substrate processing apparatus, characterized in that for vibrating in the vertical direction.
According to claim 19,
The solder ball tool applies a positive pressure to the pickup unit to separate the solder ball from the solder ball pickup unit in an air blowing method.

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