The present invention relates to a terminal connection structure for electrically connecting a conductor and at least one terminal electrode of an electronic component.
A terminal connection structure that connects terminals of power devices by using a stacked conductor in which insulators and conductors are alternately superposed on each other near the terminal electrodes of the power devices is a well-known terminal connection structure for electrically connecting a conductor and terminal electrodes of an electronic component (for example, Patent Literature 1).
The terminal connection structure disclosed in Patent Literature 1 is such that male parts and female parts are brought into close contact with each other by swaging. The male parts are inserted into the contact-terminal insertion holes provided in the conductors and the insulators of the stacked conductor and the female parts are formed with a larger diameter than that of the contact-terminal insertion holes.
Patent Literature 1: Japanese Patent Application Laid-open No. 2007-19372
The terminal connection structure disclosed in Patent Literature 1 described above is formed such that the swaging portions are formed into a circular shape so as to facilitate swaging. In recent power devices, some power semiconductor modules for high current applications have a plurality of fastening points on one terminal electrode on the module side. Because the fastening points are, for example, disposed one after another in a lateral direction, the module terminal is formed into, for example, a rectangular shape such that the fastening points are aligned.
It is possible to form a swaging structure in the conventional technologies into a rectangular shape in order to follow such a rectangular module terminal. However, with a rectangular swaging structure, it is difficult to evenly apply a swaging force over the entire perimeter of the rectangular shape, and thus it has been difficult to actually use a rectangular swaging structure.
Thus, a module terminal having a plurality of fastening points has a circular swaging portion at each fastening point and this reduces the contact area ratio that is the ratio of the contact area of the conductor and the terminal electrode at the swaging portions to the footprint of the terminal electrode in which the fastening points are aligned. Because the power module having a plurality of fastening points is often used for high current applications, a reduction in the contact area ratio poses a problem of an increase in the temperature of the contact portions. Therefore, there is a demand for a terminal connection structure that can increase the contact area ratio.
The present invention has been achieved in view of the above and an object of the present invention is to provide a terminal connection structure that can increase the contact area ratio.
In order to solve the above problems and achieve the object, an aspect of the present invention is a terminal connection structure for electrically connecting a conductor and at least one terminal electrode of an electronic component. The terminal electrode includes a plurality of connection terminals, the terminal connection structure includes a male part that includes a hole portion into which a fastening member is inserted, and a female part into which the male part is inserted and that includes hole portions equivalent in number to the connection terminals, the conductor is secured by being sandwiched between the female part and the male part and swaging the hole portion of the male part, and the conductor is secured to the electronic component with the fastening member inserted into the hole portion of the male part and fastening mechanisms provided to the respective connection terminals.
According to the present invention, an effect is obtained where the contact area ratio can be increased and thus an increase in the temperature of the contact portion can be suppressed.
A terminal connection structure according to exemplary embodiments of the present invention will be explained below with reference to the accompanying drawings. The present invention is not limited to the following embodiments.
First, an explanation will be given, with reference to
As illustrated in
In the first element pair 10, the drain of the MOSFET and the cathode of the FWD are electrically connected to each other in the module to form a connection portion 10a; the terminal portion drawn out from the connection portion 10a forms a first terminal electrode M1; the source of the MOSFET and the anode of the FWD are electrically connected to each other in the module to form a connection portion 10b; and the terminal portion drawn out from the connection portion 10b forms a second terminal electrode M2. In the second element pair 12, the source of the MOSFET and the anode of the FWD are electrically connected to each other in the module to form a connection portion 12a; the terminal portion drawn out from the connection portion 12a forms a third terminal electrode M3; the drain of the MOSFET and the cathode of the FWD are electrically connected to each other in the module to form a connection portion 12b; and the connection portion 12b is electrically connected to the second terminal electrode M2.
The first terminal electrode M1, the second terminal electrode M2, and the third terminal electrode M3 are each formed into a rectangular shape and are provided on one main surface side of the package 2. The first terminal electrode M1 and the third terminal electrode M3 are disposed in the central portion of the package 2 such that their longitudinal direction is parallel to the longitudinal direction of the package 2 and they are aligned in a direction orthogonal to the longitudinal direction of the package 2. The second terminal electrode M2 is disposed on one end portion side in the longitudinal direction of the package 2 and is disposed such that its longitudinal direction matches the direction orthogonal to the longitudinal direction of the package 2. Each of the first terminal electrode M1, the second terminal electrode M2, and the third terminal electrode M3 is provided with three holes 32, and a nut 34, which is a fastening mechanism, is provided in each of the holes 32. The holes 32 and the nuts 34 constitute fastening points of the first terminal electrode M1, the second terminal electrode M2, and the third terminal electrode M3, which are terminal electrodes of the power module 1. The function of the nuts 34 will be described later.
Next, an explanation will be given, with reference to
The components of the terminal connection structure according to the first embodiment include male parts 21 illustrated in
The female part 22 has a rectangular or elliptical shape (hereinafter both shapes are collectively referred to as a “horizontally elongated shape”) in cross section as illustrated in
Swaging of the shaft portions 21b of the male parts 21 to the female part 22 can be performed by, as illustrated in
The swaged conductor 25 is fastened to the power module 1 by, as illustrated in
Next, an explanation will be given, with reference to
In
In contrast,
As is apparent from the comparison of
In contrast, with the terminal connection structure in the first embodiment, the female part, which is a part located on the power module 1 side and is among the parts that are in contact with the conductor 25, is formed into a horizontally elongated shape; therefore, the area in contact with the conductor 25 can be increased compared with that in the conventional technologies. Therefore, the current density can be reduced.
As described above, according to the terminal connection structure in the first embodiment, the conductor is secured by being sandwiched between the male parts, which include the hole portions into which the fastening members are inserted, and the female part, into which the male parts are inserted and which includes hole portions equivalent in number to the connection terminals of the power module, and then swaging the hole portions of the male parts, and the power module is secured to the conductor with the fastening members inserted into the hole portions of the male parts and the fastening mechanisms provided to the connection terminals. In this way, the contact area ratio can be increased without reducing the swaging force. Therefore, an increase in the temperature of the contact portion can be suppressed.
Moreover, the terminal connection structure according to the first embodiment uses one female part with respect to a plurality of connection terminals. Thus, swaging operations can be performed continuously in a single operation. Therefore, the swaging operations can be performed efficiently.
On the fastening member side, female parts 52 are provided. The female parts 52 are provided with hole portions 52a into which the shaft portions 51b of the male part 51 are inserted and are each formed into a circular cross-sectional shape when viewed from the direction A1. Unlike the first embodiment, the configuration is such that three separate female parts 52 are provided. The first embodiment employs, as illustrated in
With the terminal connection structure according to the second embodiment configured as above, the configuration is such that the male part and the female part in the structure in the first embodiment are interchanged. Thus, swaging is performed near the conductor that is to be sandwiched; therefore, the conductor can be secured by a smaller swaging force than that in the first embodiment.
With the terminal connection structure according to the third embodiment configured as above, the configuration is such that the male part and the female part in the structure in the first embodiment are interchanged. Thus, swaging is performed near the conductor that is to be sandwiched; therefore, the conductor can be secured by a smaller swaging force than that in the first embodiment.
Moreover, with the terminal connection structure according to the third embodiment, because one female part is used with respect to a plurality of connection terminals, swaging operations can be performed continuously in a single operation. Therefore, the swaging operations can be performed efficiently.
The terminal connection structure according to the fourth embodiment configured as above is equivalent in configuration to that in the first embodiment; therefore, effects similar to those in the first embodiment can be obtained.
Moreover, with the terminal connection structure according to the fourth embodiment, because one female part and one male part are used with respect to a plurality of connection terminals, swaging operations can be performed continuously in a single operation. Therefore, the swaging operations can be performed efficiently.
In the first embodiment, as illustrated in
The first to fifth embodiments have been explained with a power module as an example; however, they can be applied to any electronic component that needs an electrical connection with a conductor.
The configurations illustrated in the first to fifth embodiments above are examples of the configuration of the present invention and can be combined with other publicly known technologies and it is obvious that they can be changed, for example, by omitting part thereof without departing from the scope of the present invention.
As described above, the present invention is useful as a terminal connection structure for electrically connecting a terminal of an electronic component and a conductor.
1 power module, 2 package, 10 first element pair, 10a connection portion, 10b connection portion, 12 second element pair, 12a, 12b connection portion, 21, 21A, male part, 21a base portion, 21b, 51b shaft portion, 21c, 51c hole portion (male part), 22, 52, 54 female part, 22a, 52a hole portion (female part), 25 conductor, 32 hole, 34 nut (fastening mechanism), 36 bolt (fastening member), 41 swage.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/065895 | 6/16/2014 | WO | 00 |