JP5819598B2 - Interposer - Google Patents

Description

  The present invention relates to an interposer, and more particularly to an interposer having a solder connection between an electronic device and a motherboard.

  The interposer will be described with reference to FIG.

  The interposer 1 has a structure in which one or a plurality of electronic devices 6 are mounted on the interposer upper surface 2, and the interposer lower surface 3 has a connection portion 5 to the mother board 7.

  The interposer 1 and the electronic device 6 are connected by a solder connection portion 4, and the interposer 1 and the mother board 7 are connected by a solder connection portion 5.

  Since the electronic device 6, the interposer 1, and the motherboard 7 have different coefficients of thermal expansion, the difference in elongation at high temperatures is applied to the solder connection portion 4 and the solder connection portion 5 as thermal stress.

  Therefore, in the interposer 1, two measures are taken in order to relieve the thermal stress applied to the solder connection portion 4 and the solder connection portion 5.

  First, thermal stress relaxation of the solder connection portion 4 will be described.

  Ideally, it is desirable to make the thermal expansion coefficient of the interposer 1 coincide with the thermal expansion coefficient of the electronic device 6, but the thermal expansion coefficient differs depending on the type of the electronic device 6, and a plurality of electronic devices 6 are connected to the interposer 1. In some cases, it is difficult to make the thermal expansion coefficients completely coincide.

  Although it is difficult to achieve perfect matching, it is desirable to select a material having a value close to the coefficient of thermal expansion of the electronic device 6 as the material for the interposer, and the coefficient of thermal expansion is lower than that of BT resin and polyimide often used for the electronic device 6 Generation of thermal stress is suppressed by using a material.

  On the other hand, for the thermal stress relaxation of the solder connection portion 5, the thermal stress is eliminated by using the same low thermal expansion coefficient material as the interposer 1 as the substrate material of the mother board 7.

  Furthermore, as described in Patent Document 1 and Patent Document 2, as a countermeasure against thermal stress, there is a structure that absorbs stress by providing a space between the mother board and the interposer and moving up and down. .

JP 2006-303239 (FIG. 1) JP2008-130678 (FIG. 1)

  The problem with the interposer shown in FIG. 5 is that both the interposer 1 and the motherboard 7 must use expensive low thermal expansion coefficient materials.

  Furthermore, when a low coefficient of thermal expansion material is used for the interposer 1, the substrate becomes highly elastic and cannot follow the warp of the electronic device 6, and stress may be applied to the solder connection portion 4.

  Patent Document 1 has a problem that a large stress is applied to the bump because the interposer itself vibrates. Further, since the bump is connected by only two sides, the structure is weak against vibration and the signal line There is also the problem that the number of

Patent Document 2 also has a problem that a large stress is applied to the bump because the interposer itself moves up and down.
[Object of invention]
An object of the present invention is to reduce the thermal stress on the solder connection portion and ensure connection reliability while using an inexpensive substrate material for the interposer.

  An interposer according to the present invention is an interposer that is provided between an electronic device and a mother board via a solder connection portion, and is characterized in that a cutout portion is provided at at least two opposing corners among the four corners of the interposer. To do.

  Since the interposer has a structure capable of absorbing the thermal stress between the motherboard and the interposer, the effect of not having to match the thermal expansion coefficients of the motherboard and the interposer is transferred.

It is the external view seen from the upper surface and side surface of the interposer. It is the external view seen from the upper surface and side surface when an electronic device is mounted in the shape of an interposer. It is a figure for demonstrating operation | movement of an interposer when the coefficient of thermal expansion of an interposer and a motherboard corresponds. It is a figure for demonstrating operation | movement of an interposer when the coefficient of thermal expansion of an interposer and a motherboard does not correspond. It is an external view for demonstrating an interposer.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

  Referring to FIG. 1, an interposer as an embodiment of the present invention is shown. The interposer needs to be flexible (low elastic modulus) to absorb thermal stress (expansion / shrinkage force) when heat is applied to the electronic device or the motherboard. The thermal stress also varies depending on the type of electronic device and the material of the motherboard, and the elastic modulus required for the interposer varies depending on the type of electronic device and motherboard selected. Therefore, the elastic modulus is a value that can absorb the thermal stress of the electronic device or the motherboard, for example, a value that is significantly smaller than the elastic modulus of the FR-4 material (22-25 GPa / 25 ° C.) (for example, a low elastic modulus of 5 GPa or less). And having a thermal expansion coefficient of 10 to 30 ppm / ° C. By making the interposer have a low elastic modulus, it becomes possible to absorb thermal stress. However, in the present invention, in order to absorb the stress caused by bending of the interposer, the shape of the interposer is characterized. .

  That is, the shape of the interposer 1 is a cross shape with four corners cut out. In the case where the number of connection signals between the interposer 1 and the mother board 7 is small, it is possible to have a shape in which the notch portion is constituted by only one diagonal.

  Thus, by making it the shape which notches four corners, the stress concentrated on one corner is disperse | distributed and it has a stronger structure with respect to a thermal stress.

  The shape and size of the interposer 1 are selected depending on the area of the electronic device 6 to be mounted and the number of connection signals to the mother board 7, so that all four corners are cut out or only one diagonal is cut out. be able to.

  On the upper surface 2 of the interposer, there is a solder connection portion 4 for mounting the electronic device 6.

  The solder connection portion 4 is an area connected on an extended line with four corners cut out.

  The mounting area of the electronic device 6 is limited to the solder connection portion 4. However, for the purpose of reducing the size of the interposer 1, only parts having a low mounting height can be mounted on the solder connection prohibited portion.

  However, in that case, the effect of reducing the elasticity of the interposer 1 is reduced.

  On the other hand, the interposer lower surface 3 has a solder connection portion 5 for connection to the mother board 7.

  The solder connection portion 5 is assigned with four sides facing each other in a cross shape.

  The pad shape of the solder connection portion 5 includes a circle, an ellipse, a square, a rectangle, and the like. Solder supply methods include solder balls and solder printing.

  An area corresponding to the back surface of the solder connection portion 5 is a solder connection prohibition portion 12 that prohibits solder connection with the mother board 7.

  When it is necessary to increase the vibration resistance of the interposer 1, only the center point C is connected to the mother board 7 by soldering.

  As another method for improving vibration resistance, there is a method of bonding the interposer 1 and the mother board 7 with a low elastic resin.

  A region sandwiched between the solder connection portion 5 and the solder connection prohibition portion 12 is a stress absorption allowance 8.

  The width of the stress absorption allowance 8 is obtained from the difference in thermal expansion coefficient between the interposer 1 and the mother board 7.

  The stress absorption allowance 8 can be further reduced in elasticity by reducing the number of substrate layers as compared with the solder connection portion, and the thermal stress on the solder connection portion 5 can be reduced.

Next, the configuration and operation of the best mode for carrying out the present invention will be described using specific examples.

  As shown in FIG. 2, the substrate material of the interposer 1 has a low elastic modulus of several GPa or less and a thermal expansion coefficient of about 10 to 30 ppm / ° C.

  The shape is a cross shape with four corners cut out. You may comprise a notch part by only one diagonal.

  The interposer upper surface 2 has a region for mounting the electronic device 6.

  On the other hand, the interposer lower surface 3 has a solder connection portion 5 for connection to the mother board 7.

  The solder connection portion 5 is assigned with four sides facing each other in a cross shape.

  The pad shape of the solder connection portion 5 includes a circle, an ellipse, a square, a rectangle, and the like. However, when the electronic device 6 is not mounted on the lower surface 3 of the interposer, a rectangle that can be firmly and securely connected by solder printing is desirable. When the electronic device 6 is mounted on the lower surface 3 of the interposer, there is a connection with a solder ball that can secure a mounting space for the electronic device 6, and the pad shape is preferably a circle.

  Further, in a region corresponding to the back surface of the solder connection portion 5, the interposer 1 and the mother board 7 are not connected by soldering, and thermal stress interference between the electronic device 6 and the mother board 7 is prevented.

  When it is necessary to increase the vibration resistance of the interposer 1, only the center point C is connected to the mother board 7 by soldering.

  As another method for improving vibration resistance, there is a method of bonding the interposer 1 and the mother board 7 with a low elastic resin.

  The stress absorption allowances 8 at four locations can be further reduced in elasticity by reducing the number of substrate layers as compared with other portions, and the thermal stress on the solder connection portion 5 can be reduced.

  Next, the operation of the interposer will be described with reference to FIGS.

The electronic device 6, the interposer 1, and the motherboard 7 have specific thermal expansion coefficients, and the amount of expansion at the time of high temperature and the manner of expansion are different.

  The interposer 1 is located between the electronic device 6 and the mother board 7 and absorbs the difference in behavior between the electronic device 6 and the mother board 7 as well as does not apply thermal stress to the solder connection portion 4 by its own thermal expansion. Play a role.

  First, the movement of the electronic device 6, the interposer 1, and the motherboard 7 when the thermal expansion coefficient 10 of the interposer and the thermal expansion coefficient 11 of the motherboard coincide with each other will be described with reference to FIG.

  Regarding the relationship between the electronic device 6 and the interposer 1, it is difficult to make the thermal expansion coefficients coincide with each other. Therefore, there is a possibility that thermal stress is always applied to the solder connection portion 4. By making it elastic, the thermal stress applied to the solder connection portion 4 can be reduced.

  Further, the warping of the electronic device 6 is also followed by reducing the elasticity of the interposer 1.

  On the other hand, regarding the relationship between the interposer 1 and the mother board 7, when the thermal expansion coefficients of both match, the elongation at high temperature also matches, so no thermal stress is applied to the solder connection portion 5.

  Further, regarding the relationship between the electronic device 6 and the mother board 7, the interposer 1 has low elasticity, and since the interposer 1 and the solder connection portion 5 of the mother board 7 are not provided on the lower surface of the electronic device 6, the behaviors of the two influence each other. It creates a situation that does not.

  Next, referring to FIG. 4, when the thermal expansion coefficient 10 of the interposer 1 and the thermal expansion coefficient 11 of the motherboard 7 do not match, the stress absorption structure of the interposer 1 absorbs the difference in thermal expansion amount, and the solder connection portion A mechanism for absorbing the thermal stress applied to 5 will be described.

  When the thermal expansion coefficient 10 of the interposer is larger than the thermal expansion coefficient 11 of the motherboard, the interposer 1 is larger in elongation than the motherboard 7 at a high temperature. In the background art, this difference in elongation is applied to the solder connection portion 5 as thermal stress. However, in the present invention, by providing a mechanism by which the interposer 1 can move up and down with the stress absorption margin 8 as a fulcrum, Application of thermal stress to the portion 7 is prevented.

DESCRIPTION OF SYMBOLS 1 Interposer 2 Interposer upper surface 3 Interposer lower surface 4 Solder connection part 5 Solder connection part 6 Electronic device 7 Motherboard 8 Stress absorption allowance 10 Interposer thermal expansion coefficient 11 Motherboard thermal expansion coefficient 12 Solder connection prohibition part

Claims (6)

An interposer provided between the electronic device and the motherboard via a solder connection part,
A notch is provided in at least two opposite corners of the four corners of the interposer,
Out of the region where the notch is extended in parallel to the end face of the interposer, the region on the center side of the interposer has a smaller number of substrate layers than the solder connection portion and continues in the direction parallel to the end face. An interposer characterized in that a region having no solder connection portion is provided, and a solder connection portion to the mother board is provided in the region on the end face side.   The interposer according to claim 1, wherein solder connection portions are provided on four sides of the interposer.   The interposer according to claim 2, further comprising a solder connection portion to the mother board at a center portion of the interposer.   The interposer according to claim 1, wherein notches are provided at all four corners of the interposer.   The interposer according to claim 1, wherein the interposer is less elastic than the mother board. An interposer provided between the electronic device and the motherboard via a solder connection part,
Provide notches at the four corners of the interposer,
Out of the region where the notch is extended in parallel to the end face of the interposer, the region on the center side of the interposer has a smaller number of substrate layers than the solder connection portion and continues in the direction parallel to the end face. Provide an area without a solder connection part, provide a solder connection part with the motherboard in the area on the end face side,
An interposer characterized in that solder connection portions with the mother board are provided only on four sides of the interposer.

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