JPH08264950A - Mounting body of electronic part - Google Patents

Abstract

PURPOSE: To markedly improve electronic parts in mounting density by a method wherein first boards are mechanically joined to the surfaces of second boards upright where connecting terminals are provided. CONSTITUTION: A first board 22 is mechanically joined upright to the surface of a second board 80 where connecting terminals are provided. Furthermore, The boards 22 and 80 are electrically connected together through such a manner that connecting terminals provided to the surface of the board 22 nearly vertical to its surface where parts are mounted are connected to connecting terminals provided to the surface of the second board 80 opposite to its surface where mounting terminals are provided. Electronic parts are mounted on both the sides of the first board 20. Mounting bodies 72 assembled as mentioned above are mounted on a back board 33 upright. As the second boards 80 are provided between the first board 22 and the back board 33, a mounting structure of this constitution is capable of dealing easily with electronic parts each provided with many terminals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mounting structure for an electronic device which operates at high speed.

[0002]

BACKGROUND OF THE INVENTION The endless advances in electronic devices (e.g., smaller size, more complexity, larger scale, faster operation) provide more benefits to people. For example, downsizing reduces the installation area, installs a large number of devices,
Mobile is realized. Moreover, more processing and more complicated processing can be realized due to complexity, large scale, and high speed operation. Further, such increased processing capacity is also being used for improving usability, and a large number of people are using the electronic devices easily and conveniently.

From the viewpoint of mounting an electronic device, all of these matters are made possible by integrating a large number of electronic circuits at a higher density, that is, by high-density mounting. In other words, miniaturization is a direct manifestation of high-density packaging. The large scale makes it possible to realize a larger scale device because higher density packaging becomes possible.
Complexity is the same as increasing scale, or shows that more diverse functions can be realized. The high-speed operation is realized because the wiring distance is shortened due to the miniaturization of the device and the propagation time of the electric signal is shortened.

Looking back on the transition of mounting technology, lug terminal connection, single-sided printed circuit board, double-sided printed circuit board, multi-layered printed circuit board, and higher density mounting have become possible while advancing with the times. This advance is a transistor,
It is well known that this has been done in parallel with the progress of electronic devices such as ICs and semiconductor devices.

There are two important packaging technologies that have achieved the high density so far. One is a bookshelf type mounting structure that has been widely known for a long time, and the other is a mounting structure using a ceramic multilayer wiring board.

The bookshelf type mounting body realizes a bookshelf type, that is, a pseudo three-dimensional semiconductor element arrangement to realize high-density wiring, although the mounting density of the printed circuit board is lower than that of the ceramic multilayer wiring board. , That is,
This is a reduction in the maximum wiring length. On the other hand, in the mounting body using the ceramic multilayer wiring board, the semiconductor elements are arranged in a plane, and the longest linear distance between the semiconductor elements is longer than that in the case where the semiconductor elements are pseudo three-dimensional. Since the board itself realizes high-density mounting, it achieves high-density electronic circuit mounting as a whole, that is, a short maximum wiring length. Hereinafter, both techniques will be described in more detail with specific examples.

First, a bookshelf type mounting structure will be described.

As shown in FIG. 21, the bookshelf type mounting structure mounts the semiconductor element 10 on a printed circuit board 20, and further connects the printed circuit board 20 to the connectors 40,
It is electrically connected to the backboard 30 via 41.

A glass epoxy copper clad laminate is generally used for each printed circuit board 20. Recently, in order to accommodate more wiring between terminals of the semiconductor element 10,
Fine wiring structure such as through hole pitch 1.27mm, 10
A multilayer printed circuit board structure of 18 layers is used.

As a technique for mounting a larger number of semiconductor elements 10 on the printed circuit board 20, there is a double-sided mounting technique using surface-mounted components. Assuming that 64 semiconductor elements 10 can be mounted on one side of the printed circuit board 20, a total of 12
Eight semiconductor elements 10 can be mounted. If 20 printed circuit boards 20 are used, a total of 2,560 semiconductor elements 10 can be obtained.
Can be accommodated.

The wirings passing through the connectors 40 and 41 and the backboard 30 are used for connecting the semiconductor elements 10 on different printed boards 20. An example of this wiring is shown in FIG.

The wiring between the most distant semiconductor elements (semiconductor element 10a--semiconductor element 10b) on this device, that is, the wiring having the maximum wiring length L is the semiconductor element 10a--the wiring on the printed circuit board 20a (FIG. 22). (C) is indicated by a solid line --- Wiring on the backboard 30 (indicated by a solid line in FIG. 22A) --- Wiring on the printed circuit board 20b ((indicated by a broken line in FIG. 22C) --- Semiconductor This is the element 10b.

Generally, the wiring of an electronic circuit is formed by a combination of x and y orthogonal wiring. The maximum wiring length L is the sum of twice the dimension W, dimension D, and dimension H in the figure, that is, L = W + D.
It becomes + 2H. The dimension W, the dimension D, and the dimension H are the approximate width, length, and height of the electronic device, respectively.

Assuming that the dimension W = 40 cm, the dimension D = 25 cm, and the dimension H = 35 cm, the maximum wiring length L
= 135 cm. The size assumed here is W = 4
The specific value of 0 cm is determined from the viewpoint of mounting 20 printed circuit boards 20 at 2 cm intervals. Similarly, the specific values of the dimension D = 25 cm and the dimension H = 35 cm are the same as those of a semiconductor element having an outer dimension of 3 cm × 2 cm, and a length and width of 8 cm.
This is supposed from the viewpoint of mounting a total of 64 pieces at intervals of several mm.

The semiconductor element having an outer dimension of 3 cm × 2 cm is a quad flat package (QFP) type having about 100 pins. To mount 128 semiconductor elements on one printed circuit board 20,
12,800 semiconductor element terminals are provided on one printed circuit board 20. When the connector 40 having 2.54 mm pitch and four rows is used, the dimension D =
Since it is about 25 cm, the number of terminals that can be installed is about 400.

As described above, in the bookshelf type mounting structure shown in FIGS. 21 and 22, 20 printed boards are mounted and the maximum wiring length L is about 135 cm. Each printed circuit board 20 can include 12,800 semiconductor element terminals and about 400 backboard connection terminals.

Next, a mounting structure using a ceramic multilayer wiring board will be described.

Regarding the mounting structure, for example, “Hardware technology, thorough pursuit of reduction of mounting delay and suppression of noise (Nikkei Electronics, December 10, 1990 issue)”, “Ha
rdwareTechnology for HITACHI M-880 Processor Group
(IEEE Electronics Components and Technology Conf
erence 1991 Proceedings, pages 693 to 703) ”and the like.

An example of a mounting structure using a ceramic multilayer wiring board is shown in FIGS. 23, 24 and 25. As shown in FIG. 23, the mounting structure is such that a plurality of modules 70 on which the semiconductor element 11 is mounted are mounted on the backboard 31 via the pins 42 and the connector 43. The module 70 has a plurality of semiconductor elements 11 mounted on a ceramic multilayer wiring board 21. Pin 42 mentioned above
Is provided on the back surface of the ceramic multilayer wiring board 21. A water cooling device 50 for cooling the semiconductor element 11 is provided on the semiconductor element side of the ceramic multilayer wiring board 21.

As its name implies, the ceramic multilayer wiring board 21 is multilayered, and fine wiring (for example, a through hole pitch of 0.45 mm) is provided inside. Therefore, even when a large number of multi-pin semiconductor elements are mounted, the signal wiring between the semiconductor elements can be accommodated in this ceramic multilayer wiring board. Various materials such as alumina-ceramic, mullite-ceramic, and glass-ceramic are used for the ceramic multilayer wiring board. Further, there is also one provided with thin film wiring and the like.
In the present specification, these are collectively referred to as "ceramic multilayer wiring board" without any particular distinction.

In the example of FIG. 23, one module 70
Further, 36 semiconductor elements 11 each having about 600 terminals are mounted. That is, the ceramic multilayer wiring board 21 is
It has 600 terminals. Also, the backboard 21
It has about 2,500 pins for connection with. The pin is used for connection with the semiconductor element 11 housed in another module 70, power supply for power supply, and the like.

The backboard 31 is a multilayer printed circuit board. This module 70 is installed on the backboard 31
Since they are mounted, a total of 720 semiconductor elements are mounted in the entire electronic device.

The internal structure of the module 70 will be described with reference to FIG.

The module 70 has a structure in which the semiconductor element 12 is mounted on one surface of the ceramic multilayer wiring board 21 and the backboard connecting pins 42 are mounted on the other surface.

The semiconductor element 11 is mounted on the ceramic multilayer wiring board 21 by CCB technology. C
The CB technique is a technique for connecting with a solder ball 14, and includes a ceramic multilayer wiring board 21 and a package 15
And, soldering pads for CCB connection are prepared in advance in a two-dimensional array. Since the pads or terminals are two-dimensionally arranged, it is possible to take out and connect many terminals from the package 15 even though the package 15 is small. That is, the mounting density of the ceramic multilayer wiring board is high. In the example of FIG. 24, about 600 connection terminals are obtained by arranging the electrodes on the package 15 of about 12 mm square at 0.45 mm intervals. Package 15
The CCB connection technology is also applied to the connection with the semiconductor element 12 such as a silicon chip therein, and the connection is performed with the solder balls 13. For this connection, the same number of terminals is secured by making the electrode interval narrower.

The fin structures 62 and 63 are used for the semiconductor element 12
The heat generated by is transmitted to the water cooling device 50 via the sealing plate 61. In the figure, holes through which cooling water circulates can be seen in the cross section of the water cooling device 50.

On the lower surface of the ceramic multilayer wiring board 21,
The pins 42 for connecting the backboard are provided in a two-dimensional array. In the example of FIG. 24, about 2500 pins 42 are obtained by arranging the pins 42 at intervals of about 2 mm on the ceramic multilayer wiring board 21 having a plane dimension of about 10 cm square.

FIG. 25 shows an example of a wiring path having the maximum wiring length in the mounting structure of the ceramic multilayer wiring board of FIG. Here, the wiring in the backboard is assumed to be x, y orthogonal wiring.

The maximum wiring length L is expressed by the following equation.

L = W + D + 2H L: Maximum wiring length W: Approximate width of backboard D: Length of backboard H: Sum of thicknesses of ceramic multilayer wiring board and connector FIG. 25 example (that is, the structure of FIG. 23) Then, about 10 cm
The corner ceramic multilayer wiring boards are mounted with a space of about 3 cm. And each dimension has a dimension W = about 65
Since the size is cm, the size D is about 50 cm, and the size H is about 1 cm, the maximum wiring length L is about 117 cm.

Therefore, the high-density mounting structure of FIG. 23 is mounted with 20 ceramic multilayer wiring boards having approximately 21,600 semiconductor element terminals and approximately 2,500 backboard connection terminals. And the maximum wiring length L is about 117c
It has become m.

In the example of FIG. 23, the size of the backboard is 70 cm × 55 cm, and its area is 3,850.
It is a square cm.

[0033]

In the future, as electronic devices become smaller, more complex, larger in scale, and operate at higher speeds, and higher densification of mounting technology is required, conventional technology cannot handle it. Absent.

With the conventional packaging structure, further densification will depend on the progress of each process used. However, process progress is generally time consuming,
It is expected that the speed of progress required for electronic devices will be insufficient. Semiconductor element terminal forming technology used here, miniaturization of wiring on the board, miniaturization of connectors and pins,
Are already quite mature technologies, and it is expected that rapid progress in the future is unlikely.

An object of the present invention is to provide a mounting body of electronic parts having a dramatically increased mounting density and an electronic device using the same.

[0036]

The present invention provides means for enabling connection from the end face of a ceramic multi-layer wiring board by using the ceramic multi-layer wiring board,
We have realized a pseudo three-dimensional arrangement of semiconductor elements, that is, double-sided mounting and a bookshelf type structure, and achieved higher packaging density.

The present invention is described in more detail below.

According to a first aspect of the present invention, there is provided an electronic component, a component mounting surface provided with terminals, and a ceramic multilayer wiring board having the electronic component mounted on the component mounting surface. The ceramic multilayer wiring board also has terminals on the side surfaces thereof, and an electronic component mounting body is provided.

As a second aspect of the present invention, a first substrate having a component mounting surface provided with terminals, a connecting terminal on one surface side, and the connecting terminal on the other surface side are provided. A second substrate having a mounting terminal having electrical continuity;
The substrate and the second substrate are at least mechanically joined in a state where the first substrate is perpendicular to a surface of the second substrate on which the connecting terminals are provided. A mounted body of electronic components is provided.

The first board is provided with connecting terminals also on a surface substantially perpendicular to the component mounting surface, and the first board and the second board are electrically connected by connecting the connecting terminals to each other. Is preferably connected to.

The first substrate and the second substrate may be ceramic multilayer wiring substrates.

Electronic parts mounted on both sides of the first substrate may be further included.

A conductive material that is arranged along the joint between the first substrate and the second substrate and is electrically connected to a predetermined circuit wiring provided on the first substrate and the second substrate. It may be provided with a flexible member.

A conductive member is provided which is arranged along the outer periphery of the first substrate and is electrically connected to predetermined circuit wirings provided on the first and second substrates. Good.

The first member electrically connected to the member.
The circuit wiring provided on the substrate and the second substrate is preferably a power supply circuit.

As a third aspect of the present invention, the above-mentioned first aspect
And a backboard provided with mounting terminals on the surface thereof, wherein the mounting body has terminals provided on the side surface of the substrate connected to the mounting terminals of the backboard, and , Standing on the above backboard,
A bookshelf-type mounting body of electronic parts is provided.

As a fourth aspect of the present invention, the above-mentioned second aspect is provided.
And a backboard having a mounting terminal on the surface thereof, wherein the mounting terminal of the second substrate is connected to the mounting terminal on the backboard. Also, a bookshelf type mounting body of electronic parts is provided, which is characterized in that it is erected on the backboard.

[0048]

The first and third aspects will be described.

Electronic components are mounted on both sides of the ceramic multilayer wiring board. Then, the terminals provided on the side surfaces of the ceramic multilayer wiring board are connected to the mounting terminals on the backboard. In this case, the mounted body is set up on the backboard.

The second and fourth aspects of the present invention will be described.

The first substrate is mechanically bonded to the second substrate in a state of being perpendicular to the surface of the second substrate on which the connecting terminals are provided. Furthermore, the electrical connection between the two boards is made by connecting the connecting terminals provided on the surface of the first board substantially perpendicular to the component mounting surface to the surface of the second board opposite to the mounting terminals. Connect it to the connecting terminal. Since the first substrate and the second substrate are both ceramic substrates, the mechanical connection between them can be made sufficiently strong. Electronic components are mounted on both surfaces of the first substrate.

The mounting body thus completed is mounted in a state where it is erected on a backboard having mounting terminals on its surface. Electrical connection between the two is made through a mounting terminal.

By providing the second substrate between the first substrate and the backboard, it is possible to easily cope with a large number of terminals.

A conductive member is provided along the joint between the first substrate and the second substrate (or along the outer periphery of the first substrate).
It is arranged and electrically connected to a predetermined circuit wiring (for example, a power supply circuit) of the first substrate and the second substrate. The member is
Since the wiring can be made thicker than the wiring inside the substrate, the voltage effect on the way can be reduced. When the member is arranged along the outer circumference of the first substrate, the first
The distance between the electronic element mounted on the substrate and the member is (relatively) uniform regardless of the position on the first substrate.
Therefore, it is possible to reduce the difference in power supply voltage supplied to each electronic element. Furthermore, these members can also serve to reinforce the mechanical bonding between the first substrate and the second substrate.

[0055]

Embodiments of the present invention will be described below with reference to the drawings.

A first embodiment of the present invention will be described.

In the first embodiment, a module on which a semiconductor element is directly mounted is constructed by using a multilayer circuit board, and a connecting pin for connecting with a backboard is provided on a side wall surface of the multilayer circuit board. The greatest feature.

FIG. 1 shows an outline of a bookshelf type mounting structure constructed by using the modules of this embodiment.

The module 71 is connected to the backboard 32 via a connector 46 provided on the backboard 32. Since the module 71 has a vertically long structure, a bookshelf type mounting structure is realized as a whole. The internal structure of the module 71 will be described later.

Ten modules 71 are mounted on one backboard 32. 72 semiconductor elements are mounted on both sides of one module 71. Therefore, a total of 720 semiconductor elements are mounted per backboard. This is the same number as the example described in the related art (see FIGS. 23, 24 and 25).

The maximum wiring length L is expressed by the following equation, as is apparent from FIG.

L = W + D + 2H In this embodiment, the size of the ceramic multilayer wiring board 22 is about 10 cm square, and the thickness of the connector 46 is about 5 mm. The dimension W is 22 cm and the dimension H is 11 cm. Since the modules 71 are mounted at intervals of about 6 cm, the dimension D is about 25 cm. Therefore, the maximum wiring length L in this embodiment is 69 cm. In the example described as the prior art (see FIGS. 23, 24 and 25), the maximum wiring length L is 117c.
It was m. Therefore, in this example, the wiring length could be shortened by about 40% as compared with the conventional example. This means that the propagation delay time of the wiring becomes about 0.6 times that of the conventional one,
The operating speed is increased to 1.7 times the reciprocal thereof.

In this embodiment, the backboard 32 has a plane dimension of 30 cm × 27 cm and its occupied area is 810 square c.
m. In the example described as the prior art (see FIG. 23), the occupied area was 3,850 square cm. Therefore,
In this embodiment, the occupied area is reduced to about 1/5.

Details of the module 71 of this embodiment are shown in FIG.
This will be described with reference to FIG.

The module 71 has a structure in which semiconductor elements are mounted on both surfaces of the ceramic multilayer wiring board 22 by using the CCB technique. Pins 44 that are electrically connected to the wiring inside the ceramic multilayer wiring board 22 (that is, a surface that is at a right angle or a substantially right angle to the surface on which components such as semiconductor elements are mounted) are provided on the side wall surface of the ceramic multilayer wiring board 22. Has been. The pin 44 is a terminal for connecting the module 71 to the backboard 32 or other external circuit. Note that in FIG. 1, a cover and the like covering the module on each side are drawn, but in FIG. 3, this is omitted.

The dimension of the side surface of the ceramic multilayer wiring board 22 used in this embodiment is 8 mm × 100 mm.
A total of 20 by mounting at a pitch of about 2 mm.
Zero (= 4 rows × 50 terminals) pins 44 are provided.

A method of mounting the pin 44 will be described.

First, the brazing terminals 45 are formed on the side surface of the multilayer ceramic circuit board 22 by using the dry thick film printing technique (see FIG. 4). Specifically, after firing the ceramic multilayer wiring board, the side surface is cut with a diamond cutter or the like, and polished as needed to partially locate the internal wiring. After that, by printing a circular conductor paste on the cueed wiring and firing it,
The brazing terminal 45 is formed. This brazing terminal 45
Are electrically connected to the internal wiring of the ceramic multilayer wiring board 22. A pin 44 shown in FIG. 6 is formed by brazing a separately prepared pin to the brazing terminal 45.

To form the brazing terminal 45, a dry thick film printing technique, a sputtering technique, a plating technique, and if necessary, an etching technique and other techniques can be used.

In the first embodiment described above, the pins 44 for connecting to the backboard 32 and the like are arranged on the side surface of the ceramic multilayer wiring board 22. Therefore, the bookshelf type mounting structure and the double-sided mounting of the ceramic multilayer wiring board 22 are possible, and the mounting density twice as high as the conventional one can be realized. If the number of semiconductor elements is the same as the conventional one, the ceramic multilayer wiring board 2
The area of 2 may be half, and the plane dimension of the ceramic multilayer circuit board may be 0.7 times. Further, the wiring length can be approximately 0.7 times. Since the wiring delay time becomes 0.7 times, the operation speed of the circuit can be increased to about 1.5 times its reciprocal.

"First substrate" in the claims
Is the ceramic multilayer wiring board 22 in this embodiment.
Is equivalent to The “mounting terminals” provided on the backboard correspond to the terminals in the connector 46.

The module capable of adopting the bookshelf type structure similar to that of this embodiment is not limited to the one shown in FIG. Another example of the module is shown in FIGS.

The module 71 'shown in FIG. 5 is characterized by having a heat dissipation structure. Other points are the same as the module 71 (FIG. 3). The module 7
In the semiconductor element 11 mounted on 1 ', the heat conduction fin 6
3 is attached. The sealing plate 61 is also provided with heat conducting fins 62 that mesh with the heat conducting fins 63. The heat transmitted from the semiconductor element 11 through these is carried away by the water cooling device 50. Further, in this example, the semiconductor element 11 and the like are hermetically sealed by the ceramic multilayer wiring substrate 22, the sealing plate 61, and the sealing side plate 66.

The module 71 "shown in FIG. 6 is a module in which the module 71 (FIG. 3) is mounted on one side. The other points are the same as those of the module 71. The module 71" mounted on one side is adopted. Even in such a case, it is possible to obtain a mounting density close to that when the module 71 is adopted by narrowing the interval between the connectors 46.

A second embodiment of the present invention will be described.

In the second embodiment, a module for directly mounting a semiconductor element is provided on a side wall surface of a multilayer circuit board with a connection expansion board, and connection pins for connection with a backboard are provided on the connection expansion board. This is the main feature.

FIG. 7 shows an outline of a bookshelf type mounting structure constructed by using the modules of this embodiment.

The module 72 is connected to the backboard 33 via the connector 47. Since the module 72 has a vertically long structure, a bookshelf type mounting structure is realized.

Ten modules 72 are mounted on one backboard 33. 72 semiconductor elements 11 are mounted on both sides of one module 72.
Therefore, a total of 720 semiconductor elements are mounted per backboard. This is the same number as the example described in the related art (see FIGS. 23, 24 and 25).

The maximum wiring length L is expressed by the following equation, as is apparent from FIG.

L = W + D + 2H.

In this embodiment, the ceramic multilayer wiring board 2 is used.
The size of 2 is about 10 cm square and the thickness of the connector 47 is about 5 m.
There is m. The dimension W is 22 cm and the dimension H is 11 cm.
Since the modules 72 are mounted at intervals of about 7 cm, the dimension D is about 35 cm. Therefore, the maximum wiring length L in this example is 79 cm. Therefore, in this example, the wiring length could be shortened by about 33% as compared with the conventional example. This means that the propagation delay time of the wiring becomes about 0.67 times that of the conventional one, so that the operation speed is increased to 1.5 times its reciprocal.

Further, in this embodiment, since the backboard 32 has a plane size of 40 cm × 27 cm, it occupies an area of 1,080 square cm, which is 3,850 square cm of the conventional mounting structure shown in FIG. The size was 0.28 times or about 3.5 times smaller than that of cm.

The module 72 in this embodiment will be described.

As shown in FIG. 9, the module 72 of this embodiment has various components (for example, semiconductor elements, water cooling device) mounted on both sides of the ceramic multilayer wiring board 23. Further, the side wall surface thereof is provided with a connection expansion board 80 having connection pins 44 electrically connected to the various components.
As described above, 72 semiconductor elements are mounted on one module 72.

On the side wall of the ceramic multilayer wiring board 23, there are provided solder ball connecting electrodes 45 which are electrically connected to some of the internal wirings 24 (see FIG. 10). The connection expansion board 80 is a multilayer wiring board, and a wiring circuit is provided inside and on the surface thereof. Therefore, in the above-mentioned electrical connection between the ceramic multilayer wiring board 23 and the connection expansion board 80, the exposed portion of the wiring 24 on the side wall and the circuit on the surface of the connection expansion board 80 are joined via the solder balls 81. This is done (see FIG. 10). That is, the electrical connection between the component and the connection pin 44 is made by [Component--solder ball 26--through hole 25
--- Internal wiring 24 --- Solder ball connection electrode 45 ---
Solder ball 81-through hole 84-wiring 82-
-Connecting pin 44]. Further, in this embodiment, a ceramic substrate is used as the connection expansion substrate 80. As a result, the mechanical connection strength between the connection expansion board 80 and the ceramic multilayer wiring board 23 can be easily obtained with a practically sufficient value.

In this embodiment, the solder ball connecting electrode 45 provided on the side surface of the multilayer ceramic wiring board 23.
Are formed by the following process.
Baking of the ceramic multilayer wiring board, cueing a part of the internal wiring on the side surface of the multilayer wiring board (cutting and polishing the board with a diamond cutter, etc.), printing a conductor paste in a circle on the cueed wiring, and baking.

In this example, the solder ball connecting electrodes were formed with a pitch of 0.45 mm. Since the size of the side wall of the substrate is 8 mm × 100 mm, the electrodes are arranged in 16 rows × 20.
It was possible to form 0 pieces, that is, a total of 3,200 pieces. In this way, because the pitch of the solder balls is fine,
Despite the small side surface area of the ceramic multilayer wiring board, it is possible to obtain a large number of connection points.

On the other hand, the connection pins 44 provided on the lower surface of the connection expansion board 80 are provided at a pitch of 1.5 mm. Since the planar dimension of the connection expansion board is 6 cm x 10 cm, 4
It was possible to provide a total of 2,640 pins, 0 rows × 66 pins.

In the second embodiment described above, the connection expansion board 80 and the pins 44 are connected to the backboard or the like.
Through the side surface of the ceramic multilayer wiring board. As a result, double-sided mounting of the ceramic multilayer wiring board is possible, and the mounting density twice as high as that of the conventional technique can be realized.

As described above, in the second embodiment, the mounting density,
With respect to the wiring length, operating speed, etc., the same effects as in the first embodiment could be obtained. That is, if the number of mounted semiconductor elements is the same as the conventional one, the area of the ceramic multilayer wiring board may be half, and the plane dimension of the ceramic board may be 0.7 times. Further, the wiring length can be approximately 0.7 times. Since the wiring delay time becomes 0.7 times, the operation speed of the circuit can be increased to about 1.5 times its reciprocal.

Further, in the second embodiment, since the connection expansion board is used, a larger number of connection pins can be provided as compared with the first embodiment.

Incidentally, in the claims, "the second"
The substrate "corresponds to the connection expansion substrate 80 in this embodiment. The" connecting terminal "provided in the first substrate corresponds to the solder ball connecting electrode 45. The second substrate provided" connecting " The “terminal” corresponds to a terminal portion connected to the solder ball connecting electrode 45 by the solder ball 81. The “mounting terminal” provided on the second substrate corresponds to the pin 44. The “mounting terminals” of the backboard correspond to the terminals included in the connector 47.

The module capable of adopting the bookshelf type structure similar to that of this embodiment is not limited to that shown in FIG. Other examples of the module are shown in FIGS.

The module shown in FIG. 12 is the module of FIG. 9 mounted on one side. It is the same as the module of FIG. 14 except that the size of the connection expansion board is about half, and the pin 44 is connected to the side surface of the ceramic multilayer wiring board through the connection expansion board using the technique according to the present invention. ing.

In the module shown in FIG. 13, the cooling mechanism is changed and the air cooling fins 66 are connected to the LSI instead of the water cooling device. The other points are the same as in FIG.

In the module shown in FIG. 14, a rod 90 is joined to the side of the connecting portion between the ceramic multilayer wiring substrate 23 and the connection expansion substrate 80 to reinforce the joining of both. Other points are basically the same as the module of FIG.

Further, in this example, the rod 90 is made of metal, so that the rod 90 can be used as a path for passing a large power supply current. In the case of assuming such a role, the rod 90 is electrically connected to the internal wiring between the ceramic multilayer wiring board 23 and the connection expansion board 80 through the through hole. That is, of the two rods 90, one is connected to the ground wiring on both the ceramic multilayer wiring board 23 and the connection expansion board 80, and the other is connected to the power supply wiring on both boards. The connection is made by soldering in this embodiment. With such a configuration, it is possible to realize power supply with a small voltage drop and a small voltage difference depending on the position.

The module shown in FIG. 15 has a T-shaped metal plate 9
1 is an example in which the joining of the ceramic multilayer wiring board 23 and the connection expansion board 80 is reinforced by 1.

Similar to the rod 90 in FIG. 14, the metal plate 91 can also be used as a path for passing a power supply current. In this case, the metal plate 91 is electrically connected to the internal wiring of each board through the side surface of the ceramic multilayer wiring board 23 and the connection expansion board 80. Therefore, also in connection of the metal plate 91, solder pads (or electrodes) are provided on the side walls of the ceramic multilayer wiring board 23 and the connection expansion board 80 by the same process as in the above embodiment.

The module shown in FIG. 16 uses the L-shaped metal plates 92 and 93 to form the ceramic multilayer wiring board 23.
This is intended to reinforce the joint between the connection expansion board 80 and the connection expansion board 80. One of these is provided on each of the left and right side surfaces of the ceramic multilayer wiring board 23 and the like. Metal plates 92, 9
Of the three, one is connected to the ground wiring and the other is connected to the power wiring. As a result, like the other examples, the voltage drop is small,
It realizes power supply with a small voltage difference depending on the position. The metal plates 92 and 93 are connected to the wiring inside the substrate through pads provided on the side walls of the ceramic multilayer wiring substrate 23 and the connection expansion substrate 80.

The module shown in FIG. 17 is provided with a metal plate 96 and terminals 97 in addition to the module shown in FIG.

The metal number 96 for the power transmission path is connected to the metal plates 92, 93 provided on the left and right of the ceramic multilayer wiring board. Therefore, these metal plates 92, 93, 96
Substantially surrounds the ceramic multilayer wiring board 23 "
The U-shaped frame is configured. By doing so, the difference in distance to each semiconductor element is reduced, and the voltage difference in power supply voltage can be further reduced.

The terminal 97 for connecting the power source is the metal plate 9
It is provided at the lower end portions of 2, 93. The power supply voltage can be directly supplied to the L-shaped metal plates 92 and 93 through the terminal 97 without using the back board and other connecting pins. As a result, the number of connection pins 44 that can be used for exchanging signals can be increased. Further, a power source bus bar 98 is installed on the back board, and the power source bus bar 9
The power supply voltage can be directly taken in from 8. Therefore, it is possible to reduce the voltage drop due to the connection pins 44 and the like, the voltage drop due to the power wiring in the backboard, and the like. Further, if the power supply connection terminal 97 is fixed with a screw 99 or the like as shown in the drawing, it also serves to fix the module to the backboard.

The metal plates 92, 93, the metal plate 96, and the terminal 97 are connected to the ceramic multilayer wiring board 23, etc. through these side walls as in the other examples.

The modules shown in FIG. 19 and FIG.
A plurality of ceramic multilayer wiring boards 23 are connected to one connection expansion board 84. In this case, the two ceramic multilayer wiring boards 23 are connected to the connection expansion board 84 through the pads (or electrodes) provided on the side wall thereof.

The module structure of FIG. 18 is similar to that of FIG.
And prepared for comparison with FIGS. 19 and 20.

In the claims, "conductive member" means the above-mentioned rod 90, metal plates 91, 92, 93, 9
It is equivalent to 6 mag.

Any of the various module structures described above can be mounted on the backboard or the like of the second embodiment.

According to the embodiments described above, double-sided pseudo three-dimensional mounting is possible using the ceramic multilayer wiring board. As a result, the packaging density could be doubled. In addition, the maximum wiring length could be reduced to 0.7 times and the propagation delay time of the wiring could be reduced to 0.7 times. For this reason,
The operating speed can be increased up to 1.5 times.

Further, according to the present invention, it becomes possible to use a bookshelf type electronic device having a high density mounting structure in which semiconductor elements are arranged in a pseudo three-dimensional arrangement by using a ceramic multilayer wiring board. As a result, the device area could be reduced to about 1/5. Further, the propagation delay time of the wiring could be reduced to 0.6 times. Therefore, the operating speed could be increased up to 1.7 times.

With such miniaturization and high speed, a more complicated and larger scale device can be realized. As described above, the present invention contributes to the development of the electronic industry.

The present invention can be applied to various types of semiconductor elements (for example, the presence or absence of a package, the presence or absence of a heat conduction fin, the presence or absence of a water cooling mechanism). Further, although a ceramic multilayer wiring board without a thin film wiring is used, these are matters for designing individual electronic circuits or electronic devices and are included in the present invention.

Further, the materials and shapes of the reinforcing plate and the rod are also matters to be designed. Furthermore, although pins and connectors are used in connection with the backboard and the like in all of the embodiments, soldering, butt pins, solder balls, elastomers, pressure welding and other methods can also be used. These are also design matters and are included in the present invention.

In the first and second embodiments, the module is vertically long, but this is also a matter of design, and it need not be vertically long. In fact, a bookshelf type mounting structure can be realized by the technique according to the present invention regardless of the vertical and horizontal widths, and therefore any vertical and horizontal widths are included in the present invention.

The essence of the present invention is to realize a mechanism that enables electrical connection from the side surface of a ceramic multilayer wiring board, and to realize a high-density mounting module using this technique. is there. It is also possible to realize a so-called bookshelf type or a pseudo three-dimensional structure in which these are arranged substantially in parallel. The present invention relates to an electronic device having this mechanism or structure wholly or partially.

[0117]

As described above, according to the present invention, pseudo three-dimensional mounting of double-sided mounting is possible by using the ceramic multilayer wiring board. As a result, high packaging density, maximum wiring length, reduction of wiring propagation delay time, and improvement of operating speed can be achieved.

Further, by utilizing the effect of miniaturization and high speed, it is possible to realize a more complicated and larger scale device. As described above, the present invention contributes to the development of the electronic industry.

[Brief description of drawings]

FIG. 1 is a perspective view showing a bookshelf type mounting structure according to a first embodiment of the present invention.

2A is a front view, FIG. 2B is a top view, and FIG. 2C is a side view of the bookshelf structure shown in FIG.

FIG. 3 is a schematic diagram showing an internal structure of a module 71.

4 is a perspective view showing an electrode 45 provided on a side wall of the ceramic multilayer wiring board 23. FIG.

FIG. 5 is another module 7 applicable to the first embodiment.
It is a schematic diagram which shows the internal structure of 1 '.

FIG. 6 is another module 7 applicable to the first embodiment.
It is a schematic diagram which shows the internal structure of 1 ".

FIG. 7 is a perspective view showing a bookshelf type mounting structure according to a second embodiment of the present invention.

8 shows the bookshelf structure shown in FIG. 7,
(A) Front view, (b) Top view, (c) Side view.

FIG. 9 is a schematic diagram showing an internal structure of a module 72.

10 is a partially enlarged view schematically showing the connection structure between the ceramic multilayer wiring board 23 and the connection expansion board 80. FIG.

11 is a perspective view showing a side wall of the ceramic multilayer wiring board 23 and an electrode 45 provided on the side wall. FIG.

FIG. 12 is a schematic diagram showing the internal structure of another module applicable to the second embodiment.

FIG. 13 is a schematic diagram showing the internal structure of another module applicable to the second embodiment.

FIG. 14 is a side view (a) and a front view (b) showing another module applicable to the second embodiment.

15 (a) is a side view and FIG. 15 (b) is a front view showing another module applicable to the second embodiment.

FIG. 16 is a side view (a) and a front view (b) showing another module applicable to the second embodiment.

17 (a) is a side view and FIG. 17 (b) is a front view showing another module applicable to the second embodiment.

FIG. 18 is a side view showing an example of a module.

FIG. 19 is a side view showing a module in which a plurality of ceramic multilayer wiring boards are attached to one connection expansion board.

FIG. 20 is a side view showing a module in which a plurality of ceramic multilayer wiring boards are attached to one connection expansion board.

FIG. 21 is a perspective view showing a conventional bookshelf structure.

22 (a) is a front view, FIG. 22 (b) is a top view, and FIG. 22 (c) is a side view showing a conventional bookshelf structure.

FIG. 23 is a perspective view showing a conventional high-density mounting structure using a ceramic multilayer wiring board.

24 is a schematic diagram showing an internal structure of a module applied to the mounting structure shown in FIG.

25A is a front view and FIG. 25B is a top view of the high-density mounting structure shown in FIG.

[Explanation of symbols]

10, 11 ... Semiconductor element 20 ... Printed circuit board, 21, 22, 23 ... Ceramic multilayer wiring board 24, 25 ... Wiring and through holes inside ceramic multilayer wiring board 30, 31, 32, 33 ... Backboard 40, 41, 43 , 46 ... Connector 45 ... Electrodes 42, 44 on the side surface of the ceramic multilayer wiring board 42, 44 ... Connection pins 50, 51 ... Water cooling device and its connector 61 ... Sealing plate 62, 63 ... Cooling fin structure 64, 65 ... Sealing Stop structure 66 ... Air-cooled fins 70, 71, 72 ... Module 80 ... Expanded connection board 81 ... Solder balls for connection between ceramic multilayer wiring board and expanded connection board 82, 83 ... Wiring and through holes inside expanded connection board 90 ... Rod 91, 92, 93, 94, 95 ... Metal plate 97 ... Terminal 98 ... Bus bar 99 ... Terminal fixing screw

Claims (10)

[Claims] 1. A ceramic multilayer wiring board having an electronic component and a component mounting surface on which terminals are provided, and having the electronic component mounted on the component mounting surface, the ceramic multilayer wiring board having a side surface thereof. An electronic component mounting body, characterized in that it also has terminals. 2. A first device having a component mounting surface provided with terminals.
A substrate; and a second substrate having a connecting terminal on one surface side and a mounting terminal having electrical continuity with the connecting terminal on the other surface side, the first substrate and the second substrate A board is at least mechanically joined in a state in which the first board is perpendicular to the surface of the second board on which the connection terminals are provided, and mounting of an electronic component is characterized in that body. 3. The first board comprises connecting terminals on a surface substantially perpendicular to the component mounting surface, and the first board and the second board are electrically connected by connecting the connecting terminals to each other. The electronic component mounting body according to claim 2, wherein the mounting body is electronically connected. 4. The electronic component package according to claim 3, wherein the first substrate and the second substrate are ceramic multilayer wiring substrates. 5. The electronic component mounting body according to claim 4, further comprising electronic components mounted on both surfaces of the first substrate. 6. The circuit board is arranged along a joint between the first board and the second board, and is electrically connected to a predetermined circuit wiring provided on the first board and the second board. The electronic component package according to claim 2, further comprising a conductive member. 7. A conductive member disposed along the outer periphery of the first substrate and electrically connected to a predetermined circuit wiring provided on the first substrate and the second substrate. The mounted body of the electronic component according to claim 2. 8. The first unit electrically connected to the member.
The circuit component provided on the substrate and the second substrate is a power circuit, and the electronic component package according to claim 6 or 7. 9. An electronic component mounting body according to claim 1, and a backboard having mounting terminals on a surface thereof, wherein the mounting body mounts terminals provided on a side surface of the substrate on the back side. A bookshelf-type mounting body of an electronic component, which is connected to the mounting terminals of a board and stands on the backboard. 10. An electronic component mounting body according to claim 2, and a backboard having mounting terminals on a surface thereof, wherein the mounting body mounts the mounting terminals of the second substrate on the back side. A bookshelf type mounting body of electronic parts, which is connected to a mounting terminal on a board and stands on the back board.