Patent Grant
9627955
This application is a related application of Japanese Patent Application No. 2014-028704 filed on Feb. 18, 2014, and claims priority thereto, and the entire contents thereof are hereby incorporated by reference into the present application.
The technique disclosed herein relates to a semiconductor module.
Japanese Patent Application Publication No. 2001-308263 (hereinbelow referred to as Patent Literature 1) discloses a semiconductor module that includes a first wiring, a second wiring, a third wiring, an upper arm-side semiconductor chip connected between the first wiring and the second wiring, and a lower arm-side semiconductor chip connected between the second wiring and the third wiring. The first wiring, the second wiring, the third wiring, the upper arm-side semiconductor chip, and the lower arm-side semiconductor chip are resin molded. Each semiconductor chip includes a switching device and a diode.
In a type of semiconductor module as the one in Patent Literature 1, a further loss reduction is desired. In order to reduce a loss in such a semiconductor module, loss reduction in the switching device and the diode becomes necessary. Losses generated in these devices include steady loss and switching loss. However, the steady loss and the switching loss are in a trade-off relationship, so it is difficult to reduce both of them simultaneously.
The inventor of the present application found that in a buck-boost circuit provided with the aforementioned type of semiconductor module, the loss generated in an upper arm in many cases has a higher steady loss ratio compared to the loss generated in a lower arm. Therefore, a semiconductor module disclosed herein comprises a first wiring; a second wiring; a third wiring; an upper arm switching device connected between the first wiring and the second wiring; an lower arm switching device connected between the second wiring and the third wiring; an upper arm diode connected between the first wiring and the second wiring such that the first wiring is connected to a cathode side; and a lower arm diode connected between the second wiring and the third wiring such that the second wiring is connected to a cathode side. At least one of the following (a) and (b) is satisfied: (a) a ratio of steady loss to switching loss of the upper arm diode is smaller than a ratio of steady loss to switching loss of the lower arm diode; and (b) a ratio of steady loss to switching loss of the upper arm switching device is smaller than a ratio of steady loss to switching loss of the lower arm switching device.
Notably, the above (a) means that the ratio of steady loss to switching loss of the upper arm diode becomes smaller than the ratio of steady loss to switching loss of the lower arm diode when the upper arm switching device and the lower arm switching device are operated under the same voltage condition. Further, the above (b) means that the ratio of steady loss to switching loss of the upper arm switching device becomes smaller than the ratio of steady loss to switching loss of the lower arm switching device when the upper arm switching device and the lower arm switching device are operated under the same voltage condition.
In the above semiconductor module, as described in the above (a) and (b), the steady loss is less likely to occur in the upper arm than in the lower arm, and the switching loss is less likely to occur in the lower arm than in the upper arm. According to this configuration, the switching loss is suppressed in the lower arm where the switching loss ratio is high, so a total amount of loss generated in the lower arm (that is, the total amount of the steady loss and the switching loss) can be reduced. Further, according to this configuration, the steady loss is suppressed in the upper arm where the steady loss ratio is high, so a total amount of loss generated in the upper arm can be reduced. Accordingly, by employing devices with different characteristics in the upper arm and the lower arm, the total amount of loss in the entire semiconductor module can be reduced.
Crystal defects of the upper arm diode may be fewer than crystal defects of the lower arm diode.
According to this configuration, the ratio of steady loss to switching loss of the upper arm diode can be made smaller than the ratio of steady loss to switching loss of the tower arm diode.
The upper arm switching device and the lower arm switching device may be IGBTs (abbreviation of Insulated Gate Bipolar Transistors). A p-type impurity density of a collector region of the upper arm switching device may be higher than a p-type impurity density of a collector region of the lower arm switching device.
According to this configuration, the ratio of steady loss to switching loss of the IGBT being the upper arm switching device can be made smaller than the ratio of steady loss to switching loss of the IGBT being the lower arm switching device.
Another semiconductor module disclosed herein also comprises a first wiring; a second wiring; a third wiring; an upper arm switching device connected between the first wiring and the second wiring; an lower arm switching device connected between the second wiring and the third wiring; an upper arm diode connected between the first wiring and the second wiring such that the first wiring is connected to a cathode side; and an lower arm diode connected between the second wiring and the third wiring such that the second wiring is connected to a cathode side. A ratio of a device area of the upper arm diode to a device area of the upper arm switching device is larger than a ratio of a device area of the lower arm diode to a device area of the lower arm switching device.
By a keen study of the inventor of the present application, it has been found that in many cases an energization amount of the upper arm diode is greater than an energization amount of the lower arm diode, and an energization amount of the lower arm switching device is greater than an energization amount of the upper arm switching device.
In this regard, in the aforementioned semiconductor module, the ratio of the device area of the upper arm diode to the device area of the upper arm switching device is greater than the ratio of the device area of the lower arm diode to the device area of the lower arm switching device. Here, “device area” includes an area of a region where the switching device and the diode are formed as seen in a plan view. The term “device area” may in other words be described as an area of a region where current flows. That is, large current can flow through the upper arm diode as compared to the lower arm diode. Further, a large current can be flown through the lower arm switching device as compared to the upper arm switching device. Thus, in the above semiconductor module, the respective devices can suitably be operated upon its usage.
A total device area of the upper area switching device and the upper arm diode may be equal to a total device area of the lower arm switching device and the lower arm diode.
According to this configuration, an upper arm-side device (that is, the upper arm switching device and the upper arm diode) and a lower arm-side device (that is, the lower arm switching device and the lower arm diode) can be configured by a same size. By configuring the semiconductor module by using the devices of the same size, arrangement structures of the devices and wirings in the module do not become complicated.
The upper arm switching device and the upper arm diode may be provided in a first semiconductor substrate. The lower arm switching device and the lower arm diode may be provided in a second semiconductor substrate.
According to this configuration, the upper arm switching device and the upper area diode do not have to be provided on separate substrates. Similarly, the lower arm switching device and the lower arm diode do not have to be provided on separate substrates.
A substrate area of the first semiconductor substrate may be equal to a substrate area of the second semiconductor substrate.
According to this configuration, the upper arm-side device and the lower arm-side device can be configured by the same size. By configuring the semiconductor module by using the devices of the same size, the arrangement structures of the devices and wirings in the module do not become complicated.
The upper arm switching device, the upper arm diode, the lower arm switching device, and the lower arm diode may be integrally resin molded.
According to this configuration, the respective devices configuring the semiconductor module can be suppressed from exhibiting variations,
As shown in
The high potential wiring 300, the output wiring 400, and the low potential wiring 500 are respectively configured by wiring materials having conductivity, for example, by aluminum plates.
A negative terminal of the battery 600 is connected to the low potential wiring 500. A positive terminal of the battery 600 is connected to one end of a reactance 610. The other end of the reactance 610 is connected to the output wiring 400. Further, a filter capacitor 620 is connected between the output wiring 400 and the low potential wiring 500 by being parallel to a serial circuit of the battery 600 and the reactance 610.
The inverter circuit 700 is connected between the high potential wiring 300 and the low potential wiring 500. Further, a main capacitor 710 is connected between the high potential wiring 300 and the low potential wiring 500 by being parallel to the inverter circuit 700.
The upper arm semiconductor device 100 comprises an upper arm switching device 110 and an upper arm diode 120. The upper arm switching device 110 is an IGBT. A collector of the upper arm switching device 110 is connected to the high potential wiring 300, and an emitter of the upper arm switching device 110 is connected to the output wiring 400. The upper arm diode 120 is connected between the high potential wiring 300 and the output wiring 400 so that the high potential wiring 300 is connected to the cathode.
The lower arm semiconductor device 200 comprises a lower arm switching device 210 and a lower arm diode 220. The lower arm switching device 210 is an IGBT. A collector of the lower arm switching device 210 is connected to the output wiring 400, and an emitter of the lower arm switching device 210 is connected to the low potential wiring 500. The lower arm diode 220 is connected between the output wiring 400 and the low potential wiring 500 so that the output wiring 400 is connected to its cathode side.
The circuit of
Further, in a state where the voltage of the high potential wiring 300 is higher than the predetermined value, a current flows in a second return current circuit 17 as shown by an arrow 17 in
In the present embodiment, as shown in
With reference to
An n-type emitter region 20, a p-type body region 30, an n-type drift region 40, an n-type buffer region 70, and a p-type collector region 80 are provided in the upper arm switching device 110. An upper surface of the emitter region 20 makes ohmic contact with a front surface electrode 60. A lower surface of the collector region 80 makes ohmic contact with a rear surface electrode 90. Further, the upper arm switching device 110 is provided with a plurality of gate trenches 32. A trench gate electrode 36 covered by a gate insulating film 34 is provided inside each of the gate trenches 32. Upper surfaces of the trench gate electrodes 36 are covered by insulating layers 38, and are insulated from the front surface electrode 60. The trench gate electrodes 36 are electrically connected to an external component at positions not shown.
A p-type anode region 50, an n-type drift region 40, an n-type buffer region 70, and an n-type cathode region 85 are provided in the upper arm diode 120. An upper surface of the anode region 50 makes ohmic contact with the front surface electrode 60. A lower surface of the cathode region 85 makes ohmic contact with the rear surface electrode 90. The drift region 40 and the buffer region 70 in the upper arm diode 120 are continuous with the drift region 40 and the buffer region 70 of the upper arm switching device 110. Further, the upper arm diode 120 is provided with a plurality of gate trenches 32 similar to the upper arm switching device 110.
In the semiconductor substrate 10, a crystal defect region 44 created by implanting helium ions is present. In the crystal defect region 44, a crystal defect density is higher than its surrounding drift region 40. The crystal defect region 44 is arranged continuously over the upper arm switching device 110 and the upper arm diode 120.
In the present embodiment, the front surface electrode 60 of the upper arm semiconductor device 100 is connected to the output wiring 400, and the rear surface electrode 90 is connected to the high potential wiring 300 (see
Further, the lower arm semiconductor device 200 has a similar plan-view structure as the upper arm semiconductor device 100 shown in
In the present embodiment, a device area of the upper arm switching device 110 and a device area of the lower arm switching device 210 are equal. Similarly, a device area of the upper arm diode 120 and a device area of the lower arm diode 220 are equal. In the present description, a “device area” means an area of a region where the switching device and the diode are provided when the semiconductor substrate 10 is seen in its plan view. The term “device area” may also be referred to as an area of a region where a current flows. Thus, in the present embodiment, a ratio of the device area of the upper arm diode 120 to the device area of the upper arm switching device 110 is equal to a ratio of the device area of the lower arm diode 220 to the device area of the lower arm switching device 210. Further, a total device area of the upper arm switching device 110 and the upper arm diode 120 is equal to a total device area of the lower arm switching device 210 and the lower arm diode 220.
Further, a cross sectional structure of the lower arm semiconductor device 200 is almost the same as the cross sectional structure of the upper arm semiconductor device 100 shown in
In the first embodiment, a p-type impurity density of the collector region 80 of the upper aura switching device 110 is higher than a p-type impurity density of the collector region 80 of the lower arm switching device 210. Notably, in the first embodiment, a crystal defect amount in the crystal defect region 44 in the upper arm diode 120 is substantially the same as a crystal defect amount in the crystal defect region 44 in the lower arm diode 220. Here, the term “impurity density” may be an average impurity density in the relevant region. Thus, for example, when the collector region 80 of the upper arm switching device 110 is to be formed, a larger amount of p-type impurity (for example, phosphorus) may be implanted therein than in forming the collector region 80 of the lower arm switching device 210. Due to this, the upper arm switching device 110 has a stricture that is more resistant to steady loss as compared to the lower arm switching device 210 but more prone to switching loss. That is, if the switching devices 110, 210 are operated under a same condition, the upper arm switching device 110 would have a smaller steady loss as compared to the lower arm switching device 210, however would have a larger switching loss.
In the circuit shown in
Further, the lower arm switching device 210 that operates under a condition prone to the switching loss has the structure resistant to the switching loss, so the switching loss can be reduced. Further, although the lower arm switching device 210 has the structure more prone to the steady loss, not so much steady loss is generated under the operating condition of the lower arm switching device 210. Due to this, a total amount of loss generated in the lower arm switching device 210 is small.
As described above, according to the configuration of the first embodiment, a total amount of loss generated in the semiconductor module 2 can be reduced.
Further, in the present embodiment, the upper arm switching device 110 and the upper arm diode 120 are arranged within one piece of semiconductor substrate 10. Similarly, the lower arm switching device 210 and the lower arm diode 220 are arranged within one piece of semiconductor substrate 10. Due to this, in the present embodiment, the upper arm switching device 110 and the upper arm diode 120 do not have to be arranged on separate substrates. Similarly, the lower arm switching device and the lower arm diode do not have to be arranged on separate substrates.
Further, in the present embodiment, the total device area of the upper arm switching device 110 and the upper arm diode 120 is equal to the total device area of the lower arm switching device 210 and the lower arm diode 220. Further, in the present embodiment, a substrate area of the semiconductor substrate 10 on which the upper arm semiconductor device 100 is arranged is equal to a substrate area of the semiconductor substrate 10 on which the lower arm semiconductor device 200 is arranged. Due to this, the semiconductor module 2 can be fabricated using the devices of the same size, so arrangement structures of the devices and wirings in the module do not become complicated.
The high potential wiring 300 is an example of a “first wiring”. The output wiring 400 is an example of a “second wiring”. The low potential wiring 500 is an example of a “third wiring”. The drift region 40, the buffer region 70, and the cathode region 85 of the upper arm diode 120 (or lower arm diode 220) are examples of a “cathode region”. The semiconductor substrate 10 on which the upper arm semiconductor device 100 is arranged is an example of a “first semiconductor substrate”. The semiconductor substrate 10 on which the lower arm semiconductor device 200 is arranged is an example of a “second semiconductor substrate”.
In a second embodiment, the p-type impurity density of the collector region 80 is substantially the same in the upper arm switching device 110 and the lower arm switching device 210. However, in the second embodiment, the crystal defect amount in the crystal defect region 44 of the upper arm diode 120 is less than the crystal defect amount in the crystal defect region 44 of the lower arm diode 220. For example, when the crystal defect region 44 of the lower arm diode 220 is formed, a greater amount of helium ions is implanted therein than when the crystal defect region 44 of the upper arm diode 120 is formed. Other configurations of the second embodiment are similar to those of the first embodiment.
The crystal defect region 44 reduces the switching loss in the diode (loss generated upon when the diode performs reverse recovery), and on the other hand increases the steady loss of the diode. Thus, in the upper arm diode 120 having the smaller crystal defect amount has the structure more resistant to the steady loss but more prone to the switching loss than the lower arm diode 220 having the great crystal defect amount.
In the circuit shown in
Further, the lower arm diode 220 that operates under a condition prone to the switching loss has the structure resistant to the switching loss, so the switching loss can be reduced. Further, although the lower arm diode 220 has the structure more prone to the steady loss, not so much steady loss is generated under the operating condition of the lower arm diode 220. Due to this, a total amount of loss generated in the lower arm diode 220 is small.
As described above, according to the configuration of the second embodiment, the total amount of loss generated in the semiconductor module 2 can be reduced.
As described above, in the first embodiment, a ratio of steady loss to switching loss in the upper arm switching device 110 is smaller than a ratio of steady loss to switching loss in the lower arm switching device 210. In the second embodiment, a ratio of steady loss to switching loss in the upper arm diode 120 is smaller than a ratio of steady loss to switching loss in the lower arm diode 220. By setting the ratios of steady loss to switching loss of the respective devices as in the first and second embodiments, the total amount of loss generated in the semiconductor module as a whole can be reduced.
Notably, a difference may be provided in the ratios of steady loss to switching loss between the upper arm and the lower arm by a method different from those of the first and second embodiments. Further, both structures of the first and second embodiments may be employed in one semiconductor module 2.
In a third embodiment, the p-type impurity density of the collector region 80 of the upper arm switching device 110 is substantially the same as the p-type impurity density of the collector region 80 of the lower arm switching device 210. Further, the crystal defect amount in the crystal defect region 44 of the upper arm diode 120 is substantially the same as the crystal defect amount in the crystal defect region 44 of the lower arm diode 220. However, in the third embodiment, as shown in
As shown in
In the circuit shown in
Further, as shown in
Further, as a modification of the third embodiment, as shown in
As above, specific examples of the present invention have been described in detail, however, these are mere exemplary indications and thus do not limit the scope of the claims. The art described in the claims includes modifications and variations of the specific examples presented above. For example, the following modifications may be employed.
(Modification 1) In the respective embodiments as above, as shown
(Modification 2) In the respective embodiments as above, the substrate area of the semiconductor substrate 10 on which the upper arm semiconductor device 100 is arranged is equal to the substrate area of the semiconductor substrate 10 on which the lower arm semiconductor device 200 is arranged. Not being limited hereto, the substrate area of the semiconductor substrate 10 of the upper arm semiconductor device 100 may be different from the substrate area of the semiconductor substrate 10 of the lower arm semiconductor device 200.
(Modification 3) In the respective embodiments as above, the upper arm semiconductor device 100 comprises the upper arm switching device 110 and the upper arm diode 120 on the one piece of semiconductor substrate 10. Similarly, the lower arm semiconductor device 200 comprises the lower arm switching device 210 and the lower area diode 220 on the one piece of semiconductor substrate 10. Not being limited hereto, the upper arm switching device 110 and the upper arm diode 120 may be provided on separate substrates. The lower arm switching device 210 and the lower arm diode 220 may also be provided on separate substrates.
(Modification 4) In the respective embodiments as above, the total device area of the upper arm switching device 110 and the upper arm diode 120 is equal to the total device area of the lower arm switching device 210 and the lower arm diode 220. Not being limited hereto, the total device area of the upper arm switching device 110 and the upper arm diode 120 may be different from the total device area of the lower arm switching device 210 and the lower arm diode 220.
(Modification 5) In the respective embodiments as above, the upper arm switching device 110 and the lower arm switching device 210 are IGBTs. However, the switching devices are not limited to being IGBTs, but may for example be any voluntary switching devices such as MOSFETs (abbreviation of Medal-Oxide-Semiconductor Field-Effect Transistor) or the like.
Technical features described in the description and the drawings may technically be useful alone or in various combinations, and are not limited to the combinations as originally claimed. Further, the art described in the description and the drawings may concurrently achieve a plurality of aims, and technical significance thereof resides in achieving any one of such aims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2014-028704 | Feb 2014 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2015/050291 | 1/7/2015 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2015/125507 | 8/27/2015 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 5101244 | Mori et al. | Mar 1992 | A |
| 20010033477 | Inoue et al. | Oct 2001 | A1 |
| 20090225578 | Kitabatake | Sep 2009 | A1 |
| 20100244092 | Ishikawa et al. | Sep 2010 | A1 |
| 20110267781 | Takayanagi et al. | Nov 2011 | A1 |
| 20120212170 | Matsui | Aug 2012 | A1 |
| 20150378376 | Matsui | Dec 2015 | A1 |
| Number | Date | Country |
|---|---|---|
| H03-195376 | Aug 1991 | JP |
| H08-306859 | Nov 1996 | JP |
| 10108474 | Apr 1998 | JP |
| 2001-308263 | Nov 2001 | JP |
| 2010-199628 | Sep 2010 | JP |
| 2010-232576 | Oct 2010 | JP |
| 2011-233722 | Nov 2011 | JP |
| 2013-051272 | Mar 2013 | JP |
| 2013-131774 | Jul 2013 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20160352211 A1 | Dec 2016 | US |
