1. Technical Field
The present invention relates to a sensor package in which a semiconductor sensor chip is accommodated.
2. Related Art
For example, technologies disclosed in Patent Documents 1 to 3 are well known as a measure to relax an external stress in a mounting structure of a semiconductor element such as a semiconductor chip and a semiconductor sensor.
The technology disclosed in Patent Document 1 is a technology related to a resin mold package which the semiconductor chip is mounted on and accommodated in. Specifically, as illustrated in
The technology disclosed in Patent Document 2 is a technology related to a flip-chip BGA package on which the semiconductor chip is mounted. Specifically, as illustrated in
The technology disclosed in Patent Document 3 is a technology related to a sensor package in which a semiconductor sensor chip is accommodated. Specifically, as illustrated in
In the technology disclosed in Patent Document 1, the bottom surface 103 of the portion 102 on which the semiconductor chip 101 is mounted is raised by the inverted V-shape in order to relax the stress, and a space is provided between the resin mold package 100 and the mounting board. Therefore, a height of the resin mold package 100 increases by the space. In a configuration of the Patent Document 1, it is difficult that the stress is relaxed while a low-profile package is constructed. Additionally, because the bottom surface 103 of the portion 102 on which the semiconductor chip 101 is mounted is formed into the inverted V-shape, the resin mold package 100 is in point contact with the mounting board. Therefore, possibly the connection reliability between the resin mold package 100 and the mounting board is degraded, or the resin mold package 100 is broken due to a stress concentration.
In the technology disclosed in Patent Document 2, the BGA solder ball 203 is also formed between the grooves 204 on the surface on the opposite side to the semiconductor chip 201. The BGA solder ball 203 between the grooves 204 is also connected to the motherboard when the flip-chip BGA package is partially mounted on the motherboard. Therefore, possibly the stress is transmitted from the motherboard to a mounting region on which semiconductor chip 201 is mounted in the flip-chip BGA board 202.
Additionally, in the package of Patent Document 2, the groove 204 is formed in the rear surface of the position where the semiconductor chip 201 is mounted along the external form of the semiconductor chip 201 or the outer periphery of the external form. Similarly, in the sensor package of Patent Document 3, the groove 304 is formed along the four sides of the semiconductor sensor chip 301. Unfortunately injection molding is hardly performed in the case that the structure in which the groove is formed in the package along the four sides of the semiconductor element mounting region is formed by the injection molding.
Generally, in the case that the groove is formed along the four sides of the semiconductor element mounting region by the injection molding, a metallic mold used in the injection molding has four projections corresponding to the groove along the four sides. A prismatic tube is formed by the four projections.
In
Therefore, the injection molding is hardly performed in the stress relaxation structure of the conventional mounting package disclosed in Patent Documents 2 and 3.
One or more embodiments of the present invention provides a sensor package in which the injection molding can easily be performed to the stress relaxation structure including the groove, in which the injection molding is hardly performed in the conventional technology, while the stress relaxation effect is maintained.
A sensor package according to one or more embodiments of the present invention includes: a semiconductor sensor chip; and a package body that has a semiconductor sensor chip mounting region on which the semiconductor sensor chip is mounted, the package body being a resin injection molded product. Herein, a groove is formed in a rear surface on an opposite side to a surface, on which the semiconductor sensor chip is mounted, so as to surround the semiconductor sensor chip mounting region, and a coupling section is formed in the rear surface to couple a resin portion inside the groove and a resin portion outside the groove.
According to the configuration, the external stress generated in mounting the sensor package is relaxed by the groove because the groove is formed in the rear surface on the opposite side to the surface, on which the semiconductor sensor chip is mounted, so as to surround the semiconductor sensor chip mounting region. Accordingly, the deformation of the semiconductor sensor chip mounting region due to the sensor package mounting is reduced, so that an influence of the external force applied to the semiconductor sensor chip can be decreased.
Additionally, according to the configuration, the coupling section is formed in the rear surface in order to couple the resin portion inside the groove and resin portion outside the groove, the metallic mold used in the injection molding for the groove structure includes the notch corresponding to the coupling section. During the resin injection molding, the notch acts as the inflow port through which the resin flows into the inside region of the groove, the resin flows easily into the inside region of the groove, and the inside region of the groove is sufficiently filled with the resin. Therefore, with the above configuration, the short-molding-free package can be constructed.
As described above, according to the configuration, one or more embodiments of the present invention can provide the sensor package in which the injection molding can easily be performed to the stress relaxation structure including the groove, in which the injection molding is hardly performed in the conventional technology, while the stress relaxation effect is maintained.
According to one or more embodiments of the present invention, advantageously the injection molding can easily be performed to the stress relaxation structure including the groove in which the injection molding is hardly performed in the conventional technology while the stress relaxation effect is maintained.
a)-(e) illustrate a schematic configuration of a sensor package according to one or more embodiments of the present invention,
a)-(d) are views for explaining an effect of the sensor package in
a)-(b) are views for explaining the stress relaxation effect of the sensor package in
a)-(d) illustrate[a schematic configuration of a sensor package according to a first modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a second modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a third modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a fourth modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a fifth modification,
a)-(e) illustrate a schematic configuration of a sensor package according to a sixth modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a seventh modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a ninth modification,
a)-(d) illustrate a schematic configuration of a sensor package according to a tenth modification,
a)-(d) illustrate a schematic configuration of a sensor package according to an eleventh modification,
a)-(b) illustrate a configuration of a sensor package disclosed in Patent Document 3,
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In embodiments of the invention, numerous specific details are set forth in order to provide a more thorough understanding of the invention. However, it will be apparent to one of ordinary skill in the art that the invention may be practiced without these specific details. In other instances, well-known features have not been described in detail to avoid obscuring the invention.
a)-(e) illustrate a schematic configuration of a sensor package (hereinafter referred to as the sensor package) according to one or more embodiments of the present invention,
As illustrated in
Plural terminal blocks 3 are provided in an inner bottom surface of the package body 2, and a connection pad 3a electrically connected to the semiconductor sensor chip 1 is formed in the terminal block 3. The connection pad 3a of the terminal block 3 is electrically connected to the semiconductor sensor chip 1 through a wire W.
In the package body 2, a groove 4 is formed in a rear surface 2b on an opposite side to the surface on which the semiconductor sensor chip 1 is mounted. The groove 4 is formed in the rear surface 2b so as to surround the semiconductor sensor chip mounting region 2a. The groove 4 acts as a stress relaxation unit that relaxes a stress when the sensor package is mounted on the board. The stress externally generated in mounting the sensor package is relaxed by the groove 4. In other words, a distortion generated in a bottom portion of the package body 2 in mounting the sensor package is hardly transmitted to the semiconductor sensor chip mounting region 2a. Therefore, a deformation of the semiconductor sensor chip mounting region 2a is reduced in mounting the sensor package, so that an influence of an external force applied to the semiconductor sensor chip 1 can be decreased.
A cross-linking section 5 is formed in the groove 4. The cross-linking section 5 is formed so as to cross-link sidewalls 4a and 4b constituting the groove 4. The cross-linking section 5 constitutes a coupling section that couples an inside resin portion (a resin portion on the side of the rear surface 2b including the semiconductor sensor chip mounting region 2a) surrounded by the groove 4 and a resin portion outside the groove 4.
In the case that the structure of the groove 4 in which the cross-linking section 5 is formed is formed by the injection molding, a metallic mold used in the injection molding has the configuration a notch is provided in part of the prismatic sidewall comparable to the groove 4.
The effect of the sensor package will be described in detail with reference to
In the case that the structure of the groove 4 in which the cross-linking section 5 is formed is formed by the injection molding using the metallic mold in
As can be seen from the graph in
As described above, according to the sensor package, the injection molding can easily be performed to the stress relaxation structure including the groove, in which the injection molding is hardly performed in the conventional technology, while the stress relaxation effect is maintained.
According to the sensor package, the groove 4 is formed in not the surface on which the semiconductor sensor chip 1 is mounted in the package body 2, but the rear surface 2b on the opposite side. In the case that the groove 4 is formed in the surface on which the semiconductor sensor chip 1 is mounted in the package body 2, the deformation of the semiconductor sensor chip mounting region 2a cannot be reduced.
a) is a graph illustrating a comparison result of the stress relaxation effect with respect to the configuration in which the groove 4 is formed in the surface on which the semiconductor sensor chip 1 is mounted and the configuration in which the groove 4 is formed in the rear surface on the opposite side to the surface on which the semiconductor sensor chip 1 is mounted. As illustrated in
On the other hand, the configuration (I) in which the groove 4 is formed in the rear surface on the opposite side to the surface on which the semiconductor sensor chip 1 is mounted is significantly larger than the configurations (II) and (III) in the stress relaxation effect, and the deformation of the semiconductor sensor chip mounting region 2a is reduced in the configuration (I).
The stress generated in mounting the sensor package will be described in detail with reference to
As illustrated in
On the other hand, in the configuration (III), because the groove 4 is formed in the surface on which the semiconductor sensor chip 1 is mounted, the stiffness increases locally (the deformation is hardly generated) in the region near the groove 4 in the rear surface on the opposite side to the semiconductor sensor chip 1. Therefore, in the configuration (III), the stress cannot be relaxed because the stress applied to the bottom surface is not absorbed by the groove 4 but remains.
As described above, it is found that the stress relaxation effect increases by forming the groove 4 in not the surface on which the semiconductor sensor chip 1 is mounted but the rear surface 2b on the opposite side. Therefore, according to the sensor package, the deformation of the semiconductor sensor chip mounting region 2a can be reduced.
The semiconductor sensor chip 1 accommodated in the sensor package is a diaphragm-type sensor chip including a diaphragm 1a as illustrated in
In the configuration of the sensor package, a modification of the configuration in
As illustrated in
In the case that the structure of the groove 4 including the cross-linking sections 5a to 5d is formed by the injection molding using the metallic mold, the resin flows in the inside portion of the groove 4 through the four notches comparable to the cross-linking sections 5a to 5d. Therefore, the inside region surrounded by the groove 4 can surely be filled with the resin.
In the configuration of the sensor package, another modification of the configuration in
As illustrated in
In the injection molding, the pressure at which the resin is injected runs short on the downstream side in the resin flow direction (a resin injection direction during the injection molding) and a short molding is easily generated. In the sensor package of the second modification, the cross-linking sections 5b and 5d are formed on the downstream side in the resin flow direction (the injection direction) L in which the injection pressure decreases, so that the sufficient injection pressure can be obtained during the injection molding. Therefore, the short molding can surely be improved. As a result, a yield ratio can be improved in the injection molding of the sensor package.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
In the sensor package of the third modification, the moldability is degraded compared with the sensor packages of the first and second modifications because the height h of each of the cross-linking sections 5a′ to 5d′ is less than the depth d of the groove 4. At the same time, the sensor package of the third modification is configured to have the stress relaxation effect higher than that of the sensor packages of the first and second modifications.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
A size of the cross-linking section 5e can largely be ensured. In the case that the structure of the groove 4 including the cross-linking section 5e is formed by the injection molding using the metallic mold, the size of the notch comparable to the cross-linking section 4e is enlarged, so that the resin can easily flow in the inside portion of the groove 4. Therefore, the inside region surrounded by the groove 4 can surely be filled with the resin.
There is no particular limitation to the shape of the cross-linking section 5e′ as long as the height h increases toward the central portion from both the ends of the extending direction of the groove 4. The cross-linking section 5e′ may have either a linear shape or a nonlinear shape.
In the configuration of the sensor package, still another modification of the configuration in
The sensor package of the fifth modification differs from the sensor packages of the first to fourth modifications in the shape of the groove 4 surrounding the semiconductor sensor chip mounting region 2a.
As illustrated in
Therefore, in the sensor package of the fifth modification, the deformation of the semiconductor sensor chip mounting region 2a due to the sensor package mounting is reduced, and the semiconductor sensor chip 1 increases a resistance property against the external force.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
In the case that the sensor package of the sixth modification is formed by the injection molding using the metallic mold, a structure object comparable to the resin portion 5′ constitutes the inflow port through which the resin flows. Generally, as illustrated in
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
The grooves 4 are formed in the two sides of the four sides of the rectangle surrounding the semiconductor sensor chip mounting region 2a, which allows the residual two sides to be ensured as the inflow port of the resin during the injection molding. Therefore, the inside region surrounded by the grooves 4 can surely be filled with the resin, and the injection molding is more easily performed.
In the sensor package of the seventh modification, the grooves 4 may be formed in at least two sides of the rectangle surrounding the semiconductor sensor chip mounting region 2a.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
The structure of the sensor package of the eighth modification can be applied to the sensor package in
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
Each of the cross-linking sections 5a to 5d cross-links the sidewall constituting the groove 4 of each side of the double rectangle. Therefore, the injection molding is easily performed.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
A flow path in which the resin flows into the semiconductor sensor chip mounting region 2a can be ensured by forming the groove 4 into the spiral shape surrounding the semiconductor sensor chip mounting region 2a. Therefore, the inside region (the semiconductor sensor chip mounting region 2a) surrounded by the grooves 4 can surely be filled with the resin, and the injection molding is more easily performed.
In the configuration of the sensor package, still another modification of the configuration in
As illustrated in
Each of the cross-linking sections 5a to 5d cross-links the sidewall constituting the groove 4 of each side of the double rectangle. Therefore, the injection molding is easily performed.
The present invention is not limited to the above modifications, but various changes can be made without departing from the scope of the present invention. The technical scope of the present invention also includes an embodiments obtained by a proper combination of technical means disclosed in the different modifications.
A sensor package according to one or more embodiments of the present invention includes: a semiconductor sensor chip; and a package body that has a semiconductor sensor chip mounting region on which the semiconductor sensor chip is mounted, the package body being a resin injection molded product. Herein, a groove is formed in a rear surface on an opposite side to a surface, on which the semiconductor sensor chip is mounted, so as to surround the semiconductor sensor chip mounting region, and a coupling section is formed in the rear surface to couple a resin portion inside the groove and a resin portion outside the groove.
Therefore, advantageously the injection molding can easily be performed to the stress relaxation structure including the groove in which the injection molding is hardly performed in the conventional technology, while the stress relaxation effect is maintained.
In the sensor package according to one or more embodiments of the present invention, the coupling section may be formed as a cross-linking section that cross-links sidewalls constituting the groove.
In the sensor package according to one or more embodiments of the present invention, the groove is formed into a rectangular shape surrounding the semiconductor sensor chip mounting region, and the coupling section is formed in the groove of each side of the rectangular shape. Therefore, during the injection molding for the groove structure, the resin flows more easily into the inside region of the groove, and the inside region of the groove can surely be filled with the resin.
In the sensor package according to one or more embodiments of the present invention, the coupling section is formed while biased onto a downstream side in a resin injection direction during injection molding from a central portion of the semiconductor sensor chip mounting region.
In the injection molding, the pressure at which the resin is injected runs short on the downstream side in the resin injection direction during the injection molding, and the short molding is easily generated. According to the above configuration, the coupling section is formed while biased onto the downstream side in the resin injection direction during the injection molding from the central portion in the semiconductor sensor chip mounting region, so that the sufficient injection pressure can be obtained during the injection molding. Therefore, according to the configuration, the short molding can surely be improved, and yield ratio can be improved in the injection molding of the sensor package.
In the sensor package according to one or more embodiments of the present invention, a height from a bottom surface of the groove in the coupling section is smaller than a depth of the groove. Therefore, the stress relaxation effect can be improved.
In the sensor package according to one or more embodiments of the present invention, the coupling section is formed such that the height from the bottom surface of the groove increases toward the central portion from both ends in an extending direction of the groove.
Therefore, the size of the coupling section can largely be ensured. The size of the notch of the metallic mold used in the injection molding for the groove structure is enlarged according to the coupling section. Accordingly, in the case that the groove structure is formed by the injection molding, the resin flows easily into the inside region of the groove. Therefore, according to the configuration, the inside region surrounded by the groove can more surely be filled with the resin.
In the sensor package according to one or more embodiments of the present invention, the groove is formed into the rectangular shape surrounding the semiconductor sensor chip mounting region, and the groove extends outward from a corner of the rectangle.
According to the configuration, the groove is formed into the rectangular shape surrounding the semiconductor sensor chip mounting region, and the groove extends outward from the corner of the rectangle, thereby relaxing the stress generated in the corner of the rectangle. Therefore, the deformation of the semiconductor sensor chip mounting region due to the sensor package mounting is reduced, and the semiconductor sensor chip increases the resistance property against the external force.
In the sensor package according to one or more embodiments of the present invention, the groove is formed in a portion except the corner of the rectangle surrounding the semiconductor sensor chip mounting region, a resin portion of the corner in which the groove is not formed constitutes the coupling section.
According to the configuration, the structure having the higher stress relaxation effect can be constructed by injecting the resin in the four directions from the four corners of the rectangle surrounding the semiconductor sensor chip mounting region.
In the sensor package according to one or more embodiments of the present invention, the groove is not formed in at least one of four sides of the rectangle surrounding the semiconductor sensor chip mounting region, the groove is formed in the residual sides, and a resin portion of the side in which the groove is not formed constitutes the coupling section. Therefore, the inside region surrounded by the grooves can surely be filled with the resin, and the injection molding is more easily performed.
In the sensor package according to one or more embodiments of the present invention, the groove is formed so as to pierce a bottom of the package body on which the semiconductor sensor chip is mounted. The semiconductor sensor chip mounting region is completely separated from the package body. Therefore, the stress applied to the semiconductor sensor chip mounting region can be decreased.
In the sensor package according to one or more embodiments of the present invention, the groove is formed into multiple rectangular shapes surrounding the semiconductor sensor chip mounting region.
Therefore, the deformation of the semiconductor sensor chip mounting region can be reduced against the external stress during the sensor package mounting.
In the sensor package according to one or more embodiments of the present invention, at least one rectangular groove in the multiple rectangular grooves is formed immediately below the semiconductor sensor chip mounting region.
Therefore, the stress remaining below the semiconductor sensor chip mounting region can be removed to increase the stress relaxation effect.
In the sensor package according to one or more embodiments of the present invention, the groove is formed into a spiral shape surrounding the semiconductor sensor chip mounting region, and a resin portion from an entrance to an exit of the spiral constitutes the coupling section.
Therefore, the flow path in which the resin flows in the semiconductor sensor chip mounting region can be ensured in performing the injection molding. Therefore, the inside region surrounded by the grooves can surely be filled with the resin, and the injection molding is more easily performed.
In the sensor package according to one or more embodiments of the present invention, the semiconductor sensor chip is a diaphragm-type sensor chip.
Because the diaphragm-type sensor chip is subject to the influence of the stress generated during the package mounting, the diaphragm-type sensor chip is the sensor chip suitably accommodated in the sensor package according to one or more embodiments of the present invention.
In the sensor package according to one or more embodiments of the present invention, the injection molding can easily be performed to the stress relaxation structure including the groove, in which the injection molding is hardly performed in the conventional technology, while the stress relaxation effect is maintained. Therefore, the sensor package according to one or more embodiments of the present invention can be applied to the sensor package in which the diaphragm-equipped semiconductor sensor such as the pressure sensor is accommodated, and the pressure sensor is used in an altimeter, a water pressure meter, and the like.
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
Number | Date | Country | Kind |
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2011-055972 | Mar 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/054082 | 2/21/2012 | WO | 00 | 10/4/2013 |