The present invention relates to a method and a device for detecting insulation degradation of a power module, which are used for the power module including an insulating resin layer (insulating sheet) and are capable of detecting degradation of the insulating sheet caused by high temperature and moisture absorption. The present invention also relates to a power module system.
It has conventionally been required for a power module to efficiently emit heat generated from a power semiconductor chip while electrical insulation is secured.
A general power module is constructed by fixing a ceramic substrate or a metal core substrate, on which circuit wiring is formed, and which carries a power semiconductor device, to a frame case made of a thermoplastic resin, filling the frame case with a silicone gel or an epoxy resin, and sealing the entirety thereof.
However, it is known that the power module of this type is high in manufacturing cost.
Therefore, a power module, which uses a lead frame and is transfer-molded by a sealing resin, has been developed in order to reduce the manufacturing cost (refer to Patent Literature 1, for example).
It is known that this type of transfer molding is excellent in productivity, thereby reducing the manufacturing cost, and has high reliability in the heat cycle characteristic, the power cycle characteristic, and the like because the entirety is covered with the resin having a high elastic modulus, which is different from the silicone gel.
On the other hand, the power module is often used in an environment having a high temperature and a high humidity while a high voltage is applied, and hence the power module possibly fails due to degradation of the insulating sheet. Accordingly, it is necessary to take some measures.
In the above-mentioned Patent Literature 1, in order to improve the heat discharge characteristic, a circuit board and a package for resin molding in which a lead frame is provided on a metal plate while an insulation layer is interposed therebetween is proposed for household and industrial modules, and an inexpensive power module excellent in heat discharge characteristic from the semiconductor chip to the metal plate is realized by resin sealing of carrying out transfer molding once.
However, according to the conventional technology described above, considering an actual environment in which a power module is used, there is a problem in that the power module is often used under influence of a high temperature, a high humidity, and vibrations, and materials based on an organic epoxy resin especially absorb humidity in a high-temperature/high-humidity environment, resulting in a degradation of an insulation characteristic.
Moreover, in a power module operating at a high voltage, it is important to maintain the insulation characteristic thereof. However, the power module described in Patent Literature 1 is used in a high-temperature/high-humidity environment while a high voltage is applied between the metal plate and the lead frame, and thus there is a problem that the insulation can become defective as a result of degradation of the insulating layer as the operation time increases.
Particularly, in recent years, power modules are often used for onboard vehicle application, and a failure of the power module leads to a serious problem depending on the case. Hence, a certain failsafe design is preferably employed, but a particular countermeasure has not been realized yet.
The present invention has been made in view of the above-mentioned problems, and therefore has an object to provide a method and device for detecting insulation degradation of a power module which enable failsafe control by, in a transfer-mold type power module having an insulating sheet structure employing an epoxy resin as a sealing material or a case type power module employing a silicone gel (or an epoxy resin) as a sealing material, detecting, before an insulation characteristic of an insulating layer (insulating sheet) is degraded to breakdown, a characteristic change of a current value of a current flowing through the insulating sheet, and reporting the insulation abnormality before the power module fails in response to the detection result.
According to the present invention, there is provided a device for detecting insulation degradation of a power module, including: current detection means for sampling and detecting a current value of a current flowing through an insulating sheet of the power module at a predetermined time interval; calculation means for determining, based on the current value, a state in which an insulation characteristic of the insulating sheet is so degraded that breakdown is imminent, and outputting a degradation determination result when the calculation means determines that the insulating sheet is in the state immediately before the breakdown; current storage means for storing a current value at a previous sampling time point; and alarm means for generating an alarm in response to the degradation determination result, in which the calculation means outputs the degradation determination result when a current value at a present sampling time point exceeds ten times the current value at the previous sampling time point.
According to the present invention, in a power module having the insulating sheet structure employing an epoxy resin as the sealing material, the degradation of the insulating sheet can be detected in advance by detecting the current value of the current flowing through the insulating sheet, and instability resulting from a failure of the power module caused by the insulation degradation of the insulating sheet can thus be prevented. As a result, the remarkable operation/effect which cannot be realized by the conventional technology can be provided.
A detailed description is now given of a first embodiment of the present invention with reference to the drawings.
A description is first given of a power module having an insulating sheet structure to which the first embodiment of the present invention is applied.
In
The semiconductor chip 1 is mounted on the heat spreader 2, and the copper foil 4 is in close contact with a rear surface of the heat spreader 2 through the intermediation of the insulating sheet 3. The insulating sheet 3 is disposed between the heat spreader 2 and the copper foil 4 in close contact with each other.
The lead frame 5a is connected to the semiconductor chip 1 via the bonding wire 6, and the lead frame 5b is directly connected to the heat spreader 2.
All the components mentioned above are encapsulated using the epoxy resin 7 by means of the transfer molding method.
With the construction of
In
The copper wiring board 9 is placed on the heat spreader 2 through the intermediation of the insulating sheet 3, the semiconductor chips 1 are mounted on the copper wiring board 9, and the terminals 5 are connected thereto.
The insulating sheet 3 is placed between the copper wiring board 9 on which the semiconductor chips 1 are mounted and the heat spreader 2 in close contact therewith.
With the construction of
In
The current detection means 10 detects the current value i of the current flowing through the insulating sheet 3 via the lead frame 5b and the copper foil 4 of
The calculation means 11 carries out comparison between the current value i detected by the current detection means 10 and the reference current ir set by the reference current setting means 13, and outputs the degradation determination result of YES to the alarm means 12 when a relationship of i>ir is satisfied.
Note that, the current value i is sampled at the predetermined time interval in the current detection means 10, and the calculation means 11 outputs the degradation determination result of YES when the current value i at the sampling time point exceeds the reference current ir corresponding to a current value immediately before breakdown of the insulating sheet.
The alarm means 12 reports the state in which the power module is immediately before a failure (a few minutes to a few tens of hours to occurrence of a failure) by means of an audio drive or light emission in response to the degradation determination result of YES.
Note that, the reference current ir set by the reference current setting means 13 is set to a current value slightly smaller than a current value corresponding to the insulation degradation of the insulating sheet 3. Moreover, though the reference current ir may be acquired in advance from an experimental result, the reference current ir may be arbitrarily set according to the voltage applied to the insulating sheet 3 or a material or the thickness of the insulating sheet 3.
A description is now given of an operation principle illustrated in
As described above, the power module is generally exposed to a high-temperature/high-humidity environment, and if the power module is used for a long period in the high-temperature/high-humidity environment, the insulating sheet 3, which has absorbed moisture, degrades in terms of electrical characteristics, mechanical characteristics, and thermal characteristics, and the insulation degradation can finally cause defective insulation.
As is apparent from
Moreover, though the insulation breakdown periods are different due to a variation among the respective three power modules, it can also be understood that the changes in the current value immediately before the breakdown of the insulating sheet 3 are steep.
We could recognize in detail the change in the current value immediately before the breakdown of the insulating sheet 3 by shortening the sampling interval for the current value to thereby record the current value at a high speed.
In
As is apparent from
It is also confirmed that the period from a time point of the appearance of the phenomenon in which the current flowing through the insulating sheet 3 drastically increases by one digit (ten times) to the insulation breakdown of the insulating sheet 3 takes a few minutes to a few tens of hours according to an experimental result.
In other words, the precursory period until the insulation breakdown is an insulation degradation period in which the insulating sheet 3 reaches the insulation breakdown, and it can be understood that the insulation degradation before the breakdown of the insulating sheet 3 can be detected based on the characteristic of the current change immediately before the insulation breakdown.
Specifically, the calculation means 11 of
As described above, the device for detecting insulation degradation of a power module of
Moreover, the current i is sampled at the predetermined time interval, and the calculation means 11 outputs the degradation determination result of YES when the current value i at the sampling time point exceeds the reference current ir corresponding to the current value immediately before the breakdown of the insulating sheet 3. Therefore, the degradation of the insulating sheet 3 can be detected in advance.
Failsafe control is thus provided by detecting the characteristic change of the current value of the current flowing through the insulating sheet before the insulation characteristic of the insulating layer (insulating sheet) degrades to breakdown, and reporting the abnormality before the power module fails in response to the detection result.
In other words, the failure of the power module caused by the insulation degradation of the insulating sheet 3 can be detected beforehand, and can be addressed immediately before the failure.
Though, in
In
The current storage means 14 stores the current value i(n−1) at the previous sampling time point, and inputs the previous current value i(n−1) to the calculation means 11A.
The calculation means 11A carries out comparison between the current value in at the present sampling time point from the current detection means 10 and the current value i(n−1) at the previous sampling time point from the current storage means 14, and outputs the degradation determination result of YES when the ratio therebetween exceeds ten to one, that is, “in/i(n−1)>10”.
The current detection means 10 always samples the current value i of the current flowing through the insulating sheet 3 at a predetermined sampling speed during the operation of the power module, and inputs the current value in for each sampling into the calculation means 11A and the current storage means 14.
The current storage means 14 stores the current value at each of the sampling time points from the current detection means 10, and always inputs the current value i(n−1) which is acquired one sampling period before the present sampling time point into the calculation means 11A.
As a result, the calculation means 11A can always compare the current value i(n−1) one sampling period before and the current value in sampled at the present time point with each other, and determines that the insulating sheet 3 is in the insulation degradation state and outputs the degradation determination result of YES (alarm signal) to the alarm means 12 only when the present current value in exceeds ten times the previous current value i(n−1).
As described above, the device for detecting insulation degradation of a power module according to the first embodiment (
As a result, as described above, the degradation of the insulating sheet 3 can be detected in advance, and a failure of the power module caused by the insulation degradation of the insulating sheet 3 can be detected beforehand.
Moreover, a method of detecting insulation degradation of a power module which provides similar operation/effect can be realized by replacing each of the means 10, 11A, 12, and 14 in
Though the current value in at the present sampling time point and the current value i(n−1) at the previous sampling time point are compared with each other in the calculation means 11A according to the first embodiment (
In
In this case, the current detection means 10 inputs the current value i to the current differentiation means 15, and the differentiated current di is input to the calculation means 11B.
When the differentiated current di of the current value i at the sampling time point exceeds the reference differentiated current dir, the calculation means 11B outputs the degradation determination result of YES, thereby driving the alarm means 12.
Specifically, during the operation of the power module, the current detection means 10 detects the current value i of the current flowing through the insulating sheet 3, and inputs the current value i to the current differentiation means 15, and the current differentiation means 15 calculates the differentiated current di and inputs the differentiated current di to the calculation means 11B.
The calculation means 11B compares the differentiated current di and the reference differentiated current dir, and outputs the degradation determination result of YES (alarm signal) to the alarm means 12 only when the relationship “di>dir” is satisfied and the differentiated current di thus exceeds the reference differentiated current dir.
Though the reference differentiated current dir varies depending on the voltage applied to the insulating sheet 3 and the material of the insulating sheet 3, the reference differentiated current dir may generally be set to 10−11 [A/sec] or larger as illustrated in
According to the above-mentioned experimental result (
As described above, the device for detecting insulation degradation of a power module according to the second embodiment of the present invention includes the current differentiation means 15 for calculating the differentiated current di of the current value i detected by the current detection means 10, and the calculation means 11B outputs the degradation determination result of YES when the differentiated current di of the current value i at the sampling time point exceeds the reference differentiated current dir. Therefore, the degradation of the insulating sheet 3 can be detected in advance as described above, and a failure of the power module caused by the insulation degradation of the insulating sheet 3 can be detected.
Moreover, a method of detecting insulation degradation of a power module which provides similar operation/effect can be realized by replacing each of the means 10, 11B, 12, 15, and 16 in
While the devices (and methods) for detecting insulation degradation of a power module are described in the first and second embodiments (
In
The antenna 21 detects a change in the current of the insulating sheet 3 by detecting an electromagnetic wave emitted from the power module 20 as an electromagnetic wave signal Sa.
In
The calculation means 11C carries out arithmetic processing using the electromagnetic signal Sa from the antenna 21 and the reference signal Sr from the reference signal setting means 22 as input information, and outputs the degradation determination result of YES to the alarm means 12 when the insulation degradation is determined.
A description is now given of an operation of the third embodiment of the present invention illustrated in
As illustrated in
The electromagnetic wave generated by the sudden fluctuation of the current value i in the power module 20 is detected by the antenna 21, and is input as the electromagnetic wave signal Sa to the calculation means 11C.
However, a voltage V always changes in the actual power module 20 due to switching on/off, and noises are generated by the voltage change. Thus, the noises due to the voltage change are detected by the antenna 21.
a) and 11(b) are timing charts illustrating a relationship between the voltage signal V and the electromagnetic signal Sa,
In
On the other hand, the electromagnetic wave signal Sa in
As illustrated in
Therefore, as illustrated in
While when the degradation occurs in the insulating sheet 3, the high level electromagnetic signal Sa is generally detected in the antenna 21, the noise signal generated by the drastic change in the voltage V is at a low level as illustrated in
The electromagnetic signal Sa and the noise signal can be discriminated from each other by setting the threshold level between the electromagnetic signal Sa at the time of occurrence of the insulation degradation and the noise signal.
The threshold level in this case corresponds to the reference signal Sr set by the reference signal setting means 22.
Specifically, the calculation means 11C receives the electromagnetic wave signal Sa detected by the antenna 21 and the reference signal Sr set by the reference signal setting means 22 as input information, carries out the comparison therebetween, and outputs the degradation determination result of YES indicating that the insulating sheet 3 is degraded to the alarm means 12 only when Sa>Sr is satisfied.
The alarm means 12, upon receiving the degradation determination result of YES (failure signal) from the calculation means 11C, prompts an operator to take countermeasures by generating an alarm indicating that the power module 20 is immediately (few minutes to few tens of hours) before the failure.
Though the reference signal Sr may be acquired from an experimental result in advance, the reference signal Sr may be arbitrarily set according to the applied voltage V of the power module 20.
As described above, the power module system according to the third embodiment (
As a result, the degradation of the insulating sheet 3 can be detected in advance and a failure of the power module 20 caused by the insulation degradation of the insulating sheet 3 can be detected.
It is to be understood that though, in the above description, the alarm means 12 which has received the degradation determination result of YES from the calculation means 11C immediately generates the alarm, the alarm may be generated at a time point when a predetermined number of the degradation determination results of YES have been received within a predetermined period in order to avoid a malfunction by providing redundancy.
Though the degradation determination signal is generated by comparing the electromagnetic signal Sa and the reference signal Sr with each other in the calculation means 11C according to the third embodiment (
In
The switching signal removing means 23 removes only the noise signal caused and generated by the turning on/off of the voltage V from the electromagnetic signal Sa input from the antenna 21, extracts only an electromagnetic signal Sb emitted at the time of the degradation of the insulating sheet 3, and inputs the electromagnetic signal Sb to the calculation means 11H.
Referring to
First, the antenna 21 disposed close to the power module 20 detects the electromagnetic wave emitted from the power module 20 as described above, and inputs the detected electromagnetic wave as the electromagnetic wave signal Sa to the switching signal removing means 23.
The switching signal removing means 23 removes the signal (noise signal caused and generated by the turning on/off of the circuit voltage V) irrelevant to the degradation of the insulating sheet 3 from the electromagnetic wave signal Sa, and inputs only the electromagnetic signal Sb generated upon the failure of the insulating sheet 3 to the calculation means 11H.
The calculation means 11H receives the electromagnetic wave signal Sb via the switching signal removing means 23 and the reference signal Sr set by the reference signal setting means 22 as input information, carries out the comparison therebetween, and outputs the degradation determination result of YES indicating that the insulating sheet 3 is degraded to the alarm means 12 only when Sb>Sr is satisfied.
Though the reference signal Sr may be acquired from an experimental result in advance, the reference signal Sr may be arbitrarily set according to the applied voltage V of the power module 20.
As described above, the power module system according to the fourth embodiment (
As a result, the degradation of the insulating sheet 3 can be detected in advance and a failure of the power module 20 caused by the insulation degradation of the insulating sheet 3 can be detected.
It is to be understood that though, in the above description, the alarm means 12 which has received the degradation determination result of YES immediately generates the alarm, the alarm may be generated at a time point when a predetermined number of the degradation determination results of YES have been received within a predetermined period.
Though the current detection means 10 is used for detecting the current value i of the current flowing through the insulating sheet 3 according to the first and second embodiments (
In
Signal processing means 26 carries out signal processing using the current signal ia from the high-speed current detection means 25 and a reference frequency fr set by reference frequency setting means 27 as input information, passes only a current signal ip (high frequency pulse signal) having a frequency equal to or higher than the reference frequency fr out of the current signal ia, and inputs the current signal ip to calculation means 11D.
The calculation means 11D carries out the arithmetic processing using the current signal ip via the signal processing means 26 and a reference current ipr set by reference current setting means 13D as input information, and inputs the degradation determination result of YES to the alarm means 12 only when the current signal ip exceeds the reference current ipr.
A description is now given of an operation of the fifth embodiment of the present invention illustrated in
As described above (
A sudden fluctuation of the current signal ia is detected by the high-speed current detection means 25 provided in the main circuit.
a) and 15(b) are timing charts illustrating a relationship between the voltage signal V applied to the main circuit and the current signal ia detected by the high-speed current detection means 25,
In
In
In
As illustrated in
As a result, the current signal (high frequency pulse) corresponding to the degradation of the insulating sheet 3 and the current signal corresponding to the voltage switching of the main circuit of the power module 20 are extracted as the current signals ip containing the high frequency components.
As is apparent from
The calculation means 11D thus uses the reference current ipr set by the reference current setting means 13D as the threshold, thereby discriminating those current signals from each other.
Specifically, the calculation means 11D receives the current signal ip and the reference current ipr set by the reference current setting means 13D as input information, carries out the comparison therebetween, and outputs the degradation determination result of YES indicating that the insulating sheet 3 is degraded to the alarm means 12 only when ip>ipr is satisfied.
The alarm means 12, upon receiving the degradation determination result of YES (failure signal) from the calculation means 11D, prompts the operator to take countermeasures by generating an alarm indicating that the power module 20 is immediately (few minutes to few tens of hours) before the failure.
Note that, though the reference current ipr may be acquired from an experimental result in advance, the reference current ipr may be arbitrarily set according to the applied voltage V of the power module 20.
As described above, according to the fifth embodiment (
As a result, the degradation of the insulating sheet 3 can be detected in advance and a failure of the power module caused by the insulation degradation of the insulating sheet can be detected.
It is to be understood that though, in the above description, the alarm means 12 which has received the degradation determination result of YES immediately generates the alarm, the alarm may be generated at a time point when a predetermined number of the degradation determination results of YES have been received within a predetermined period.
Though the current signal ip via the signal processing means 26 is compared to the reference current ipr in the calculation means 11D according to the fifth embodiment (
In
Moreover, voltage detection means 30, voltage differentiation means 31, reference differentiated voltage setting means 32, and removal period calculation means 33 are provided as circuit elements relating to the calculation means 11F and the signal extraction means 29.
The voltage detection means 30 detects the applied voltage applied to the main circuit of the power module 20 as the voltage signal V, and the voltage differentiation means 31 calculates a differentiated voltage dV by differentiating the voltage signal V with respect to time (dV/dt).
The reference differentiated voltage setting means 32 sets a reference differentiated voltage dVr serving as a determination reference value in the removal period calculation means 33.
The removal period calculation means 33 carries out comparison using the differentiated voltage dV and the reference differentiated voltage dVr as input information, and generates a removal signal G only in a period Δt in which the differentiated voltage dV exceeds the reference differentiated voltage dVr.
The signal extraction means 29 carries out arithmetic processing using the current signal ip and the removal signal G as input information, removes the current signal ip during the generation period Δt of the removal signal G, and inputs a new current signal ipg to the calculation means 11F.
The calculation means 11F carries out the arithmetic processing using the reference signal ipr set by the reference current setting means 13D and the current signal ipg as input information, and outputs the degradation determination result of YES to the alarm means 12 only when the current signal ipg exceeds the reference current ipr.
The subsequent operation of the alarm means 12 is as described in the first to fourth embodiments.
Referring to
a) is a timing chart illustrating a relationship between the voltage signal V applied to the main circuit of the power module 20 and the current signal ip from the signal processing means 26.
As illustrated in
As illustrated in
In order to address this problem, the signal extraction means 29 is provided, and the highly reliable insulation degradation determination is realized by generating the current signal ipg as illustrated in
b) is a timing chart illustrating a relationship among the current signal ip, the differentiated voltage dV, the removal signal G, and the new current signal ipg, and illustrates an operation corresponding to the functions of the removal period calculation means 33 and the signal extraction means 29.
Note that, in
As illustrated in
In other words, the period Δt in which the removal signal G is generated corresponds to a period in which the noise signal is generated when the voltage signal V is turned on/off.
The signal extraction means 29 generates the new current signal ipg by removing the signal in the period Δt corresponding to the removal signal G from the current signal ip when the removal signal G is input.
As is apparent from
The calculation means 11F can thus easily generate the highly reliable degradation determination result of YES without making a determination error.
As described above, according to the sixth embodiment (
As a result, the degradation of the insulating sheet 3 can be detected in advance and a failure of the power module 20 caused by the insulation degradation of the insulating sheet 3 can be detected.
It is to be understood that though, in the above description, the alarm means 12 which has received the degradation determination result of YES immediately generates the alarm, the alarm may be generated at a time point when a predetermined number of the degradation determination results of YES have been received within a predetermined period.
Moreover, a method of detecting insulation degradation of a power module which provides similar operation/effect can be realized by replacing each of the means by a processing step for the device for detecting insulation degradation of a power module according to any of the first to sixth embodiments described above.
Further, any of the configurations according to the first to sixth embodiments described above can be applied to the power module system according to the present invention, and it is only necessary for the power module system to include any device for detecting insulation degradation, the semiconductor chip 1 to which the power is supplied from the main circuit of the power module 20, the heat spreader 2 on which the semiconductor chip 1 is mounted, and the insulating sheet 3 placed on the rear surface of the heat spreader 2.
Number | Date | Country | Kind |
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2009-104140 | Apr 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/056017 | 4/1/2010 | WO | 00 | 10/20/2011 |