JP4318895B2 - 3D module, 3D module manufacturing method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a three-dimensional module having a structure in which module wiring boards are stacked and a method for manufacturing the same, and particularly to a three-dimensional module suitable for a case where there are a relatively large number of input / output terminals between module wiring boards or externally. Regarding the method.
[0002]
[Prior art]
Various two-dimensional high-density technologies have been developed for high-density mounting of electronic components. For example, semiconductor package miniaturization, bare chip mounting such as flip chip mounting, and the like. However, the two-dimensional density increase is approaching the limit, and the three-dimensional packaging density needs to be improved.
[0003]
FIG. 8 is a schematic diagram showing a structural example of a conventional three-dimensional module. As shown in FIG. 8A, in this three-dimensional module, each module 108 is arranged in a stacked manner, and the lead pin 114 that is an input / output pin of each module 108 is arranged in the vertical direction. It has a structure that is plugged in. Two relay wiring boards 118 may be provided in the case where both ends of each module 108 are arranged, or four in the case where each module 108 is arranged in four directions.
[0004]
Each module 108 is obtained by mounting (high density mounting) an electronic component 112 such as an IC (integrated circuit) on a module wiring board 111. Although not shown, a necessary wiring pattern is provided on the surface of each module 108. Is formed. The wiring pattern is also electrically connected to lead pins 114 provided outward from the edge of the back surface of the module wiring board 111 through wiring interlayer connections (not shown) such as through holes. For the module wiring board 111, for example, a multilayer ceramic wiring board or a resin wiring board (printed wiring board) can be used. The lead pins 114 may be provided on the front surface instead of the back surface of the module wiring board 111 in some cases.
[0005]
The lead pins 114 are attached to the module wiring board 111 by, for example, brazing when the module wiring board 111 is ceramic, or by soldering using, for example, a clip lead when the module wiring board 111 is resin.
[0006]
The relay wiring board 118 is basically a wiring board on which an electrical connection pattern between the modules 108 and an electrical connection pattern with the outside of the three-dimensional module are formed, and the lead pins 114 of the module 108 are connected. For example, a through hole is provided. For example, solder is used for connection in the through hole. In addition, as the material of the relay wiring board 118, for example, a resin with a rigid reinforcing material (for example, a glass epoxy resin) or a flexible resin (for example, polyimide) is used.
[0007]
[Problems to be solved by the invention]
In such a three-dimensional module, there are matters to be improved as described below. One is an insufficient number of lead pins 114 used for input / output of each module 108. As described above, in order to increase the number of the lead pins 114, it can be provided on the four sides of the module wiring board 111. However, as each module 108 itself is mounted at a high density, the number of inputs and outputs necessary for each module 108 inevitably increases, making it difficult to cope with this.
[0008]
Further, it is easy to cause difficulty in assembly as a three-dimensional module such as alignment of each module 108. Typically, this appears due to variations in the insertion depth of the lead pin 114 into the relay wiring board 118 in each module 108 as shown in FIG. If such a variation occurs, the electrical / mechanical connection with the relay wiring board 118 becomes poor in the worst case, or even if not so, the lead pin 114 protrudes in the lateral direction and the maximum outer dimension is larger than a predetermined value. This may cause erroneous contact with surrounding conductors.
[0009]
Further, when the relay wiring board 118 is a flexible wiring board, the mechanical rigidity as a three-dimensional module is insufficient, and thus it cannot be said that the modules 108 are fixed enough. For this reason, when a flexible wiring board is used for the relay wiring board 118, a rod-like fixing member that penetrates in the vertical direction through each module 108 is actually added to fix the relative positions of the modules 108. New processes and members are required.
[0010]
The present invention has been made in consideration of the above-described circumstances, and provides a three-dimensional module capable of at least responding to an increase in the number of input / output terminals between module wiring boards or externally, and a manufacturing method thereof. Objective.
[0011]
[Means for Solving the Problems]
In order to solve the above-described problem, a three-dimensional module according to the present invention includes first and second module wiring boards that are provided with input / output leads outward from an edge and are arranged substantially parallel to each other, and The first and second module wiring boards are arranged in a direction substantially perpendicular to the direction of the input / output leads, and are electrically connected to the first and second module wiring boards by contacting the input / output leads. And a pattern for electrical connection with the outside is formed A relay wiring board and a conductive member provided between the opposing surfaces of the first and second module wiring boards and having electrical contact with the first and second module wiring boards;
Conductive paths that communicate with each other between the first module wiring board and the second module wiring board do not pass through the relay wiring board.
[0012]
That is, each module wiring is connected by the relay wiring board and the input / output leads provided on each module wiring board. Board Perform electrical input / output with external devices Yeah. Also Between the opposing surfaces of both module wiring boards, a conductive member having electrical contact with both module wiring boards is provided. Therefore, electrical input / output between the module wiring boards arranged opposite to each other is performed directly via this conductive member without passing through the path of the input / output lead → the relay wiring board → the input / output lead. Be called .
[0013]
Therefore, in each module wiring board, it is not necessary to provide input / output leads for electrical input / output with at least the adjacent module wiring board. Therefore, it is possible to provide a three-dimensional module that can cope with an increase in the number of input / output terminals between module wiring boards or externally.
[0014]
In addition, ceramics, resin, and resin containing a reinforcing material can be used for the plate material of the module wiring board, and a rigid or flexible resin (resin containing reinforcing material) is used for the board material of the relay wiring board, for example. it can.
[0015]
In addition, the method for manufacturing a three-dimensional module according to the present invention includes first and second module wiring boards each having input / output leads outward from the edge and having land patterns for electrical connection on the surface. A step of forming, a step of disposing a conductive member on one or both of the land patterns for electrical connection of the first and second module wiring boards, and via the disposed conductive member Arranging the first and second module wiring boards substantially parallel to each other so that the first and second module wiring boards are electrically connected; and In a direction substantially perpendicular to the direction of the input / output leads The pattern for electrical connection with the outside is formed A step of arranging a relay wiring board and electrically connecting the input / output lead and the relay wiring board, wherein the first module wiring board and the second module wiring board are used as the relay wiring board. It is characterized by using the thing which does not contain the conductive path which mutually connects between.
[0016]
That is, in addition to connecting the relay wiring board and the input / output leads provided on each module wiring board for electrical input / output between the module wiring boards or the outside, between the opposing surfaces of both module wiring boards In addition, a conductive member capable of electrical contact is formed on both module wiring boards. here In the three-dimensional module according to this manufacturing method, the electrical input / output between the module wiring boards arranged opposite to each other is not performed via the path of the input / output lead → the relay wiring board → the input / output lead. Go directly through U .
[0017]
Therefore, it is not necessary to provide input / output leads for electrical input / output with at least adjacent module wiring boards in each module wiring board. Therefore, it is possible to provide a method for manufacturing a three-dimensional module that can cope with an increase in the number of input / output terminals between module wiring boards or externally.
[0018]
In this three-dimensional module manufacturing method, for example, ceramics, resin, or resin containing reinforcing material can be used for the plate material of the module wiring board. For example, rigid or flexible resin ( (Reinforcing resin) can be used.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
As an embodiment of the present invention, the conductive member is solder. By using solder, a self-alignment effect can be exhibited in the manufacturing stage, and relative alignment between modules can be performed with high accuracy by this effect.
[0020]
As an embodiment, the conductive member is a conductive resin. By using the conductive resin, a paste-like material before being cured in the manufacturing stage can be formed at a predetermined position on the module wiring board by, for example, screen printing. This can contribute to the improvement of productivity.
[0022]
Further, the three-dimensional module as an embodiment is provided between the opposing surfaces of the first and second module wiring boards, and is between the first module wiring board and the second module wiring board. A spacer is further provided to keep the distance constant. By providing the spacer, even when the conductive member is a solder or a conductive resin before curing, the distance between adjacent module wiring boards can be made relatively simple and kept in the positional relationship in the manufacturing stage. .
[0023]
As an embodiment, the relay wiring board is a flexible wiring board. Since the module wiring boards can be mechanically connected to each other by a conductive member, the mechanical rigidity as a three-dimensional module is relatively easily secured by itself. Therefore, a flexible material can be used for the relay wiring board.
[0024]
As an embodiment, the conductive member is not located in the vicinity of the edge portion of the first and second module wiring boards. By doing in this way, even if it is a case where the material of an adjacent module wiring board differs, for example, generation | occurrence | production of the shear force to the electroconductive member by the difference in an expansion coefficient can be suppressed. Therefore, reliability can be improved.
[0025]
Also, the three-dimensional module as an embodiment includes first and second module wiring boards that are respectively provided with input / output leads outward from the edge and are arranged substantially parallel to each other, and the first and second modules. A relay wiring board disposed substantially perpendicular to the direction of the input / output leads of the wiring board and electrically connected to the first and second module wiring boards by contact of the input / output leads; A conductive member provided between opposing surfaces of the first and second module wiring boards and having electrical contact with the first and second module wiring boards; In addition, the conductive path that interconnects the first module wiring board and the second module wiring board does not pass through the relay wiring board. . The number of module wiring boards is increased to 3 or more in a stacked manner.
[0026]
In the embodiment of the manufacturing method, the step of arranging the conductive member may be performed by applying a flux in advance on either or both of the land patterns for electrical connection of the first and second module wiring boards. The solder balls as the conductive members are disposed through the applied flux, and the step of disposing the first and second module wiring boards substantially parallel to each other includes the step of disposing the disposed solder. By reflowing the balls, the first and second module wiring boards are electrically connected. The module wiring boards are simply electrically connected to each other using solder balls that can be used as products.
[0027]
Also, the manufacturing method as an embodiment includes first to nth modules (n is an integer of 3 or more) each having input / output leads outward from the edge and each having a land pattern for electrical connection on the surface. A conductive member is disposed on either or both of the step of forming a wiring board and the electrical connection land pattern of the module wiring board according to the adjacent ordinal number among the first to n-th module wiring boards. The first to n-th module wiring boards are electrically connected to each other in a stacked manner through the step of performing this for each ordinal number and the disposed conductive members. A step of arranging the n-th module wiring boards in a stack according to the ordinal number, and a direction substantially perpendicular to the direction of the input / output leads of the first to n-th module wiring boards arranged in a stack And a step of electrically connecting said by arranging the relay circuit board input and output leads and said relay circuit board As the relay wiring board, one that does not include a conductive path that interconnects adjacent ones of the first to nth module wiring boards is used. To do. In this manufacturing method, the number of module wiring boards is increased to 3 or more in a stacked manner.
[0028]
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to an embodiment of the present invention from the lateral direction, and the process proceeds in the order of (a) to (c).
[0029]
First, as shown in FIG. 1A, the module 8 is manufactured. The module 8 is obtained by mounting (high-density mounting) an electronic component 12 such as an IC (integrated circuit) on a module wiring board 11. The module wiring board 11 is provided with a wiring pattern (not shown) necessary for this, and an electrical interlayer connection member (not shown) that leads the module wiring board 11 in the vertical direction. . For the plate material of the module wiring board 11, for example, ceramics, resin, or resin with reinforcing material can be used. The planar shape of the module wiring board 11 is, for example, a substantially rectangular shape of several tens of mm square or less.
[0030]
The electronic component 12 is, for example, an IC, a discrete component, a passive component, or the like. In the case of an IC, a chip sealed in a package, a bare chip connected by flip chip, or the like can be used.
[0031]
The lead pins 14 are provided from the edge of the back surface of the module wiring board 11 in the direction of extension outward of the surface, and are electrically connected to the wiring pattern in the module wiring board 11. Thereby, the lead pin 14 functions as (a part of) the input / output terminal of the module 8. The lead pins 14 may be provided on the front surface instead of the back surface of the module wiring board 11. Further, as shown in the figure, in addition to being provided in two directions on two opposite sides of the module wiring board 11, it may be provided in four directions on four sides.
[0032]
When the module wiring board 11 is made of ceramics, the lead pins 14 can withstand relatively high temperatures, for example, by brazing. When the module wiring board 11 is made of resin, the lead pins 14 are soldered by using, for example, clip leads. 11 can be attached. In addition to the above configuration, the module wiring board 11 may be formed with members necessary for the wiring board (for example, solder resist or plating as a part of the wiring pattern).
[0033]
The structure described above can be manufactured using known techniques. In addition to this, in this module 8, there are cases where electrical connection land patterns (hereinafter simply referred to as “land patterns” or “connection land patterns”) are provided on the front side and the back side of the module wiring board 11, respectively. .) 13a and 13b are provided. These land patterns 13a and 13b are used as other parts of the input / output terminals of the module 8 (that is, input / output terminals provided in addition to the lead pins 14) as will be described later. The land patterns 13a and 13b can be formed as a part of the wiring pattern described above, for example, when the wiring pattern described above is formed at a necessary position on the module wiring board 11.
[0034]
Next, as shown in FIG. 1B, a flux 15 is applied on the electrical connection land patterns 13 a and 13 b on both surfaces of the module wiring board 11. The flux 15 improves the wettability when solder melts on the land patterns 13a and 13b and increases the reliability of electrical and mechanical connection. In a normal state, the flux 15 is pasty and viscous. For the application of the flux 15, various known methods such as use of a dispenser or a screen printer can be used. As a result, the flux-coated module 9 is obtained.
[0035]
Next, as shown in FIG. 1C, the solder balls 16 are placed on the land patterns 13 b on the back surface side of the module wiring board 11. The diameter of the solder ball 16 is, for example, about 1 mm. As a mounting method, for example, a plate having the same through-hole pattern as that of the land pattern 13b is used for the screen, and the surface on the side where the land pattern 13b of the module wiring board 11 exists is located slightly below this plate. A method of flowing the solder balls 16 on the plate after alignment can be used. The solder balls 16 that have flowed are fitted into the through holes of the plate and temporarily fixed on the viscous flux 15.
[0036]
The solder balls 16 may be placed on the front surface land pattern 13a instead of being placed on the back surface land pattern 13b. As the solder balls 16 themselves, those supplied to the market as products can be used. As a result, the solder ball mounted module 10 is obtained.
[0037]
Next, as shown in FIG. 2, the solder ball mounted modules are arranged in a stacked manner. In the following description, the module names of a, b,. FIG. 2 is a continuation diagram of FIG. 1, and is a schematic view showing a process of manufacturing a three-dimensional module according to an embodiment of the present invention from the lateral direction. The same number is attached. Note that n actually assumed is about 2 to 10, for example.
[0038]
From the top module 10a to the second module 10 (n-1) from the bottom can be prepared by the process shown in FIG. However, the electrical connection land pattern 13a does not have to be provided on the front surface side of the uppermost module 10a, and therefore, it is not necessary to apply the flux 15 thereon. Further, the electrical connection land pattern 13b may not be provided on the back surface side of the lowermost module 10n. Therefore, in that case, the application of the flux 15 and the placement of the solder balls 16 on that surface are not required. .
[0039]
The land patterns 13b and the land patterns 13a on the opposing surfaces of the modules 10a,..., 10n that are adjacent to each other have their pattern positions aligned (that is, the patterns are formed in advance). . This is for the electrical and mechanical connection between these surfaces by melting of the solder balls 16.
[0040]
Further, a spacer 17 is provided between each of the modules 10a,..., 10n in order to keep the distance between the module wiring boards 11 constant when they are electrically and mechanically connected. Here, the spacer 17 is provided in the vicinity of the edge of the module wiring board 11, but its position and planar shape are appropriately determined so as not to interfere with the component parts such as the electronic parts 12 in each module. Good. The height will be described later.
[0041]
If the solder balls 16 are placed on the front surface land pattern 13a instead of being placed on the back surface land pattern 13b, the following is a matter of course. That is, the electrical connection land pattern 13b does not have to be provided on the back surface side of the lowermost module 10n. Therefore, it is not necessary to apply the flux 15 on that surface in that case. In addition, the electrical connection land pattern 13a may not be provided on the front surface side of the uppermost module 10a. Therefore, it is not necessary to apply the flux 15 and place the solder balls 16 thereon.
[0042]
When the modules 10a,..., 10n are actually stacked as described above, a state as shown in FIG. FIG. 3 is a continuation diagram of FIGS. 1 and 2, and is a schematic view showing a process of manufacturing a three-dimensional module according to an embodiment of the present invention from the lateral direction. Are given the same numbers.
[0043]
This state is a state in which the interval between the module wiring boards 11 is defined by the solder balls 16, and is not a state in which the electronic component 12 and the spacer 17 are held between the module wiring boards 11. That is, the spacer 17 has a height that does not substantially function as a spacer in this state (approximately a height smaller than the value of the diameter of the solder ball 16).
[0044]
Next, the solder ball 16 is reflowed and solidified by placing the layered arrangement described above in, for example, an environment of warm air heated by infrared rays. Thereby, as shown in FIG. 3B, solder 16 a as a conductive member is obtained between the module wiring boards 11. Here, when each solder ball 16 is melted, surface tension is generated to reduce the surface area thereof, so that the interval between the module wiring boards 11 is shortened to the interval defined by the spacer 17.
[0045]
In this state, the spacer 17 defines the interval between the module wiring boards 11 and prevents the electronic component 12 from being held in contact between the module wiring boards 11. The spacer 17 has a height that functions as a spacer in this state (approximately higher than the height of the electronic component 12). In addition, the assumed space | interval between each module wiring board 11 in this state is about 0.4 mm to 1 mm, for example, and the whole height is about 3 mm to 30 mm, for example.
[0046]
Incidentally, the following effects also exist in the process shown in FIG. That is, in the stacked arrangement shown in FIG. 3A, even if the alignment of each module in the planar direction is slightly shifted, the effect of correcting this displacement is reached during the state shown in FIG. 3B. Is demonstrated. This is because, as described above, surface tension is generated by melting of the solder balls 16, and a force acts to connect the opposing land patterns 13a and 13b in the shortest time (self-alignment effect). Therefore, the relative positional accuracy of each module is improved as a three-dimensional module after fusion connection. Thereby, the positional relationship between the lead pins 14 of each module can be finished with high accuracy.
[0047]
Furthermore, due to the self-alignment effect, the stacking process itself shown in FIG. 3A can be performed with rough accuracy such as the position of the lead pin 14 as a clue. Also, the size of each module wiring board 11 need not be the same as long as the end positions of the lead pins 14 of each module are aligned. Position accuracy is ensured by the self-alignment effect.) Thereby, the module wiring board 11 having a net area necessary for mounting can be used, and the material can be reduced in some cases.
[0048]
3B is assembled, then, as shown in FIG. 3C, the relay wiring board 18 is attached in a vertical direction so that each lead pin 14 penetrates. The relay wiring board 18 is basically a wiring board on which an electrical connection pattern between the module wiring boards 11 and an electrical connection pattern with the outside of the three-dimensional module are formed, and the lead pins 14 are connected. For example, a through hole is provided. For example, solder can be used for connection through the through hole. Two relay wiring boards 18 may be provided in the case where both ends of each module wiring board 11 are arranged, or four in the case where each module wiring board 11 is arranged in four directions.
[0049]
The relay wiring board 18 can be easily attached to the lead pins 14 with good assembly because the module wiring boards 11 are already mechanically connected to each other with the solder 16a. For the plate material of the relay wiring board 18, for example, a rigid-reinforced resin (for example, a glass epoxy resin) or a flexible resin (for example, polyimide) can be used. However, even when a flexible resin is used. The mechanical rigidity required as a three-dimensional module can be ensured. This is also after the module wiring boards 11 are mechanically connected by the solder 16a.
[0050]
The three-dimensional module according to one embodiment of the present invention can be obtained by the process described above. In this three-dimensional module, the electrical connection between the adjacent module wiring boards 11 is directly performed using the electrical connection land patterns 13a and 13b and the solder 16a. Be Therefore, it is not necessary to configure a pattern or the like between the adjacent module wiring boards 11 with the relay wiring board 18 interposed therebetween. That is, it is not necessary to provide the lead pins 14 for electrical input / output with the adjacent module wiring board 11. Therefore, it is possible to cope with an increase in the number of input / output terminals between the module wiring boards 11 and the outside.
[0051]
Further, the electrical connection between the adjacent module wiring boards 11 is directly performed using the electrical connection land patterns 13a and 13b and the solder 16a. Be Therefore, the number of wiring patterns formed on the relay wiring board 18 can be reduced together with the number of lead pins 14. That is, the total number of wiring patterns connecting the module wiring boards 11 can be reduced. As a result, the wiring length is shortened, and as a result, improvement in reliability, improvement in operating performance, cost reduction, and the like can be achieved. This is an effect obtained by having land patterns 13a and 13b for electrical connection and solder 16a in addition to the lead pins 14 as inputs and outputs of the module wiring board 11.
[0052]
Further, in the conventional configuration (for example, FIG. 8), it is necessary to determine the allocation of signals to each lead pin from the structure as a three-dimensional module, which may cause the circuit scale of each module to vary greatly. . If the circuit scale is different, some module wiring boards have a useless area, which hinders efficient component placement design. In the above embodiment, the function of each module can be easily allocated along the signal flow, and a high-density three-dimensional module can be obtained without generating a useless area.
[0053]
Further, the land patterns 13a and 13b for electrical connection can be provided on the surface of the module wiring board 11 with good flexibility. Therefore, the number can be quite large. Even in this case, the relative alignment between the module wiring boards 11 (alignment performed in advance) can be easily performed by using the end of the lead pin 14 as a reference.
[0054]
Further, in addition, in the above description, the electronic component 12 is mounted on each module wiring board 11. However, the electronic component 12 is not necessarily mounted on each module wiring board 11. Good. That is, some of the module wiring boards 11 may have wiring land patterns 13a and 13b, but may be wiring boards on which the electronic component 12 is not mounted. In this case, the module wiring board 11 functions as a kind of relay wiring board between the module wiring boards 11 positioned above and below.
[0055]
Further, the connection between the relay wiring board 18 and the module wiring board 11 can be made without using the pin-shaped lead pins 14. For example, a flexible printed wiring board can be used in place of the lead pins 14 to make a connection between the relay wiring board 18 and the module wiring board 11. In this case, for connection between the flexible printed wiring board and the module wiring board 11 or between the flexible printed wiring board and the relay wiring board 18, a known method such as connector, soldering, anisotropic conductive film or the like is used. Can be used.
[0056]
In the above description, the connection land pattern 13a on the surface on which the electronic component 12 is mounted is provided on the module wiring board 11. However, the connection land pattern 13a is provided on the semiconductor chip as the electronic component 12. It can also be provided as a pad. In this case, the semiconductor chip is placed and fixed on the module wiring board 11 with the surface of the semiconductor chip where the connection pads are present facing up.
[0057]
Further, it is not necessary for all the module wiring boards 11 to have the same plate material. For example, a mixture of a ceramic plate and a resin plate may be used. In this case, for example, a ceramic plate can be used to secure performance for a module that requires heat dissipation, and a resin plate can be used to reduce the cost for a module that does not.
[0058]
In addition, when mixed in this way, the ceramic plate and the resin plate can be made into blocks so that the occurrence of stress due to the coefficient of thermal expansion is further reduced. Further, it is more preferable to use a flexible wiring board as the relay wiring board 18 in such a case. This is because even if a difference in thermal expansion occurs between the ceramic plate and the resin plate, the relay wiring board 18 is easily deformed, and the occurrence of stress on the relay wiring board 18 can be avoided.
[0059]
In order to properly use the electrical connection land patterns 13a and 13b, the solder 16a, and the lead pins 14 as input / output terminals, for example, the latter is mainly used for a power supply line that requires a large current value. Can be adopted. This is because the land patterns 13a and 13b for electrical connection and the terminals by the solder 16a can be formed with a smaller arrangement pitch, but the lead pins 14 are limited in their fineness, for example, with an arrangement of 1.27 mm pitch. This is because it is suitable for flowing a large current.
[0060]
Next, another embodiment of the present invention will be described with reference to FIG. FIG. 4 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to another embodiment of the present invention from the lateral direction, and the process proceeds in the order of (a) and (b). In FIG. 4, the same parts as those already described are given the same reference numerals.
[0061]
This embodiment is different from the previous embodiment in that a module 10A with applied solder paste is obtained instead of the module 10 with mounted solder balls shown in FIG. As shown in FIG. 4B, the solder paste 41 is applied, for example, on both of the land patterns 13a and 13b for electrical connection. For the application of the solder paste 41, for example, a known method such as a screen printer or a dispenser can be used.
[0062]
The solder paste 41 is a paste in which fine solder particles are dispersed in a paste-like composition containing a flux or the like, and is well known as being used when, for example, a surface-mounted component is automatically mounted.
[0063]
After that, the solder paste-applied module 10A obtained as shown in FIG. 4B is put into a process substantially similar to the process shown in FIGS. Thereby, a three-dimensional module in which the electrical and mechanical connection between the module wiring boards 11 is directly made by solder can be obtained in substantially the same manner as in the above embodiment.
[0064]
Also in this embodiment, since the electrical / mechanical connection between the module wiring boards 11 is made by solder, specific effects such as a self-alignment effect can be obtained. Other advantages can also be described above in that a conductive member exists for the connection between the module wiring boards 11.
[0065]
In this embodiment, the solder paste 41 is applied to the connection land patterns 13a and 13b on both sides of the module wiring board 11, but any one can be applied as long as it can be applied to a sufficient volume. Only one may be used. Since the volume can be easily increased by applying both surfaces, the connection between the module wiring boards 11 is reliably performed.
[0066]
Next, still another embodiment of the present invention will be described with reference to FIG. FIG. 5 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to still another embodiment of the present invention from the lateral direction, and the process proceeds in the order of (a) and (b). In FIG. 5, the same parts as those already described are given the same reference numerals.
[0067]
This embodiment is different from the previous embodiments in that a module 10B with conductive bumps is obtained instead of the module 10 with solder balls placed as shown in FIG. As shown in FIG. 5B, the conductive bump 51 is formed, for example, on the land pattern 13b on the back surface of the module wiring board 11 among the electrical connection land patterns 13a and 13b. Such a conductive bump 51 can be formed by screen printing using, for example, a conductive paste instead of ink, and production efficiency can be improved by means of printing. The conductive bump 51 can be formed in a substantially conical shape as shown in the drawing using the viscosity of the conductive paste.
[0068]
The conductive paste is a paste in which metal particles (silver, gold, copper, solder, etc.) are dispersed in a paste-like resin and mixed with a volatile solvent, and dried by applying heat. Therefore, it has a property of being completely cured. The state shown in FIG. 5B is before curing.
[0069]
The conductive bump formed module 10B obtained as shown in FIG. 5 (b) is then put into a process substantially similar to the process shown in FIGS. Thereby, a three-dimensional module in which the electrical / mechanical connection between the module wiring boards 11 is made directly by the conductive bumps 51 can be obtained.
[0070]
In this case, the spacer 17 between the module wiring boards 11 is lower than the height of the conductive bump 51 shown in FIG. Then, each module wiring board 11 is positioned so that the interval between each module wiring board 11 is defined by the spacer 17 as shown in FIG. 3B, and at the same time, the head of the conductive bump 51 is plastically deformed. Thereby, electrical connection with the land pattern 13a which opposes can be established. Further, by applying heat, the conductive bumps 51 are cured and bonded to maintain the state.
[0071]
Also in this embodiment, since the conductive bump 51 exists as a conductive member for connecting the module wiring boards 11, the above-described effects can be obtained except for the self-alignment effect and the effects derived therefrom. .
[0072]
In this embodiment, the conductive bump 51 is applied to the connection land pattern 13b on the back surface of the module wiring board 11, but it is applied to the connection land pattern 13a on the front surface. Of course.
[0073]
Next, still another embodiment of the present invention will be described with reference to FIG. FIG. 6 is a schematic view showing a process of manufacturing a three-dimensional module according to still another embodiment of the present invention from the lateral direction, and the process proceeds in the order of (a), (b), and (c). To do. In FIG. 6, the same parts as those already described are given the same reference numerals.
[0074]
This embodiment is different from the previous embodiments in that instead of the solder ball mounted module 10 shown in FIG. 1C, a metal pin formed module 10C with solder paste applied is obtained. As shown in FIG. 6B, the metal pin 61 is formed, for example, on the land pattern 13b on the back surface of the module wiring board 11 among the electrical connection land patterns 13a and 13b. For the formation of such metal pins 61, for example, a technique for forming input / output metal pins used for manufacturing a PGA (pin grid array) which is a semiconductor package can be used.
[0075]
A solder paste 62 is further applied on the land pattern 13a on the front surface of the module wiring board 11 to the module 9C on which the metal pins 61 are formed. The solder paste 62 is the same as the solder paste 41 described above. The coating method is also as described above.
[0076]
After that, the module 10C with the metal pin formed solder paste applied as shown in FIG. 6C is put into a process substantially similar to the process shown in FIGS. As a result, a three-dimensional module in which the electrical / mechanical connection between the module wiring boards 11 is made directly by the metal pins 61 can be obtained.
[0077]
In this case, the electrical / mechanical connection between the metal pin 61 and the land pattern 13a facing the metal pin 61 is made by melting and solidifying the solder paste 62. Further, since the interval between the module wiring boards 11 is defined by the metal pins 61, the spacers 17 between the module wiring boards 11 are not necessary, and the assemblability is good even without the spacers 17.
[0078]
Also in this embodiment, since the metal pin 61 exists as a conductive member for connecting the module wiring boards 11, the above-described effects can be obtained except for the self-alignment effect and the effects derived therefrom.
[0079]
In this embodiment, the metal pin 61 is formed on the connection land pattern 13b on the back surface of the module wiring board 11, and the solder paste 62 is applied on the land pattern 13a on the front surface. Of course, the reverse is also possible.
[0080]
Next, still another embodiment of the present invention will be described with reference to FIG. FIG. 7 is a top view schematically showing one module used in a three-dimensional module according to still another embodiment of the present invention, and (a) and (b) are examples thereof. . In FIG. 7, the same parts as those already described are given the same reference numerals.
[0081]
In FIG. 7A, the connection land pattern 13a (not shown but the same applies to the land pattern 13b) is arranged so as to be distributed almost evenly on the module wiring board 11. 7B, the connecting land pattern 13a is not arranged near the edge of the module wiring board 11. In FIG.
[0082]
When the land pattern 13a is arranged as shown in FIG. 7B, it is convenient when the plate material of each module wiring board 11 is different, especially when each module wiring board 11 is large to some extent. This is because, if the coefficient of thermal expansion of each module wiring board 11 is different in a three-dimensional module, a shear stress is generated in the conductive member between the module wiring boards 11, and this shear stress deteriorates reliability over time. Because it brings.
[0083]
When the land pattern 13a is arranged at the center, the displacement due to the difference in the coefficient of thermal expansion is smaller, and therefore the shear stress is also reduced. In other words, larger module wiring boards 11 can be used. The arrangement pattern of the connection land pattern 13a as a whole may be a circle, an ellipse, or the like in addition to a rectangle as shown. In this case, the arrangement of the individual land patterns 13a is not limited to the lattice shape, but may be a radial shape.
[0084]
【The invention's effect】
As described above in detail, according to the present invention, a conductive member having electrical contact with both module wiring boards is provided between the opposing surfaces of both module wiring boards. Therefore, electrical input / output between the module wiring boards arranged opposite to each other should be performed directly via this conductive member, not via the path of the input / output lead → the relay wiring board → the input / output lead. Can do. Therefore, in each module wiring board, it is not necessary to provide input / output leads for electrical input / output with at least the adjacent module wiring board. Therefore, it is possible to provide a three-dimensional module that can cope with an increase in the number of input / output terminals between module wiring boards or externally.
[Brief description of the drawings]
FIG. 1 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to an embodiment of the present invention as viewed from the side.
FIG. 2 is a continuation diagram of FIG. 1 and is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to an embodiment of the present invention from a lateral direction.
FIG. 3 is a continuation diagram of FIGS. 1 and 2 and is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to an embodiment of the present invention from a lateral direction.
FIG. 4 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to another embodiment of the present invention from the lateral direction.
FIG. 5 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to still another embodiment of the present invention from the lateral direction.
FIG. 6 is a schematic diagram illustrating a process of manufacturing a three-dimensional module according to still another embodiment of the present invention from the lateral direction.
FIG. 7 is a top view schematically showing one module used for a three-dimensional module according to still another embodiment of the present invention.
FIG. 8 is a schematic diagram showing an example of the structure of a conventional three-dimensional module.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 8 ... Module 9 ... Flux application module 9C ... Metal pin formation module 10 ... Solder ball mounting module 10A ... Solder paste application module 10B ... Conductive bump formation module 10C ... Metal pin formation solder paste application module DESCRIPTION OF SYMBOLS 11 ... Module wiring board 12 ... Electronic component 13a, 13b ... Electrical connection land pattern 14 ... Lead pin 15 ... Flux 16 ... Solder ball 16a ... Solder 17 ... Spacer 41 ... Solder paste 51 ... Conductive bump 61 ... Metal pin 62 ... Solder paste

Claims (10)

First and second module wiring boards each provided with input / output leads outward from the edge and disposed substantially parallel to each other;
The first and second module wiring boards are arranged in a direction substantially perpendicular to the direction of the input / output leads, and are electrically connected to the first and second module wiring boards by contacting the input / output leads. And, a relay wiring board on which a pattern for electrical connection with the outside is formed ,
A conductive member provided between opposing surfaces of the first and second module wiring boards and having electrical contact with the first and second module wiring boards;
A three-dimensional module, wherein a conductive path that connects the first module wiring board and the second module wiring board to each other does not pass through the relay wiring board.   The three-dimensional module according to claim 1, wherein the conductive member is solder.   The three-dimensional module according to claim 1, wherein the conductive member is a conductive resin.   A spacer provided between the opposing surfaces of the first and second module wiring boards and further maintaining a constant distance between the first module wiring board and the second module wiring board; The three-dimensional module according to claim 1.   The three-dimensional module according to claim 1, wherein the relay wiring board is a flexible wiring board.   The three-dimensional module according to claim 1, wherein the conductive member is not located near the edge of the first and second module wiring boards. First to nth (n is an integer of 3 or more) module wiring boards each having input / output leads outward from the edge and arranged substantially in parallel,
The first to nth module wiring boards are arranged in a direction substantially perpendicular to the direction of the input / output leads, and are electrically connected to the first to nth module wiring boards by contacting the input / output leads. Relay wiring board,
A conductive member provided between the opposing surfaces of adjacent module wiring boards of the first to nth module wiring boards, and having electrical contact with the adjacent module wiring boards;
The three-dimensional module characterized in that a conductive path interconnecting adjacent ones of the first to n-th module wiring boards does not pass through the relay wiring board. Forming first and second module wiring boards each having input / output leads outward from the edge and each having a land pattern for electrical connection on the surface;
Disposing a conductive member on either or both of the electrically connecting land patterns of the first and second module wiring boards;
Arranging the first and second module wiring boards substantially parallel to each other so that the first and second module wiring boards are electrically connected via the arranged conductive members;
A relay wiring board in which a pattern for electrical connection with the outside is formed in a direction substantially perpendicular to the direction of the input / output leads of the first and second module wiring boards , and the input / output leads And connecting the relay wiring board electrically,
Manufacturing the three-dimensional module, wherein the relay wiring board does not include a conductive path that interconnects the first module wiring board and the second module wiring board. Method. The step of disposing a conductive member is performed by applying a flux in advance on one or both of the land patterns for electrical connection of the first and second module wiring boards, and via the applied flux. A solder ball as the conductive member is disposed;
In the step of arranging the first and second module wiring boards substantially parallel to each other, the first and second module wiring boards are electrically connected by reflowing the arranged solder balls. The method for manufacturing a three-dimensional module according to claim 8, wherein the three-dimensional module is manufactured. Forming first to nth (n is an integer of 3 or more) module wiring boards each having input / output leads outward from the edge and each having a land pattern for electrical connection on the surface;
A conductive member is disposed on either or both of the electrical connection land patterns of the module wiring boards according to the adjacent ordinal numbers among the first to n-th module wiring boards, and this is performed for each ordinal number. Process,
The first to n-th module wiring boards are laminated according to the ordinal number so that the first to n-th module wiring boards are stacked and electrically connected via the arranged conductive members. The step of arranging
A relay wiring board is arranged in a direction substantially perpendicular to the direction of the input / output leads of the first to nth module wiring boards arranged in a stacked manner to electrically connect the input / output leads and the relay wiring board. Connecting, and
A relay wiring board that does not include a conductive path that interconnects adjacent ones of the first to nth module wiring boards is used. Production method.

Images