System, computing device, and method for detecting abnormal cooling of electric power conversion device

Abstract

The purpose of the present invention is to provide a technique for detecting an abnormality inside a semiconductor module, a TIM, or a cooler during operation of an electric power conversion device, and identifying the location at which the abnormality has occurred.　For this purpose, a system for detecting a cooling abnormality in an electric power conversion device according to the present invention comprises an electric power conversion device and a computing device, the computing device being provided with: a thermal resistance prediction unit that calculates the thermal resistance between a semiconductor module and a cooler and the thermal resistance between the cooler and a refrigerant, on the basis of the internal temperature history of the semiconductor module in actual operation, the temperature history of the cooler in actual operation, the temperature history of the refrigerant in actual operation, and the heat generation amount history of the semiconductor module in actual operation; and an abnormality determination unit that determines a cooling abnormality on the basis of at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the refrigerant, the temperature history of the refrigerant in actual operation, and the heat generation amount history of the semiconductor module in actual operation.

Description

System for Detecting Cooling Abnormalities in a Power Conversion Device, Computing Device for Detection, and Detection Method 【0001】 The present invention relates to a system for detecting cooling abnormalities in a power conversion device that supplies power to a motor or the like mounted on a railway vehicle, a computing device for detection, and a detection method. 【0002】 In a railway vehicle, generally, a power conversion device for controlling the power supplied to a driving motor is mounted under the floor. The power conversion device is provided with a power converter composed of semiconductor elements that perform current switching to perform DC / AC power conversion. In semiconductor elements, heat is generated during energization and switching. When the semiconductor elements become high temperature due to this heat, there is concern about a decrease in conversion efficiency and deterioration of the elements, so it is necessary to cool and control the semiconductor elements so that they are within a predetermined temperature range. 【0003】 As a cooling method for the power conversion device, a cooler such as a heat sink is brought into contact with the heat dissipation base of a power semiconductor module (hereinafter referred to as a semiconductor module) incorporating semiconductor elements via a TIM (Thermal Interface Material) or the like, and a cooling method using an air cooling method or a water cooling method is used. If an abnormality occurs in these cooling systems and the cooling efficiency decreases, output limitation and maintenance of the device are required. In order to shorten the downtime and maintenance period of the device, a cooling abnormality detection system that can identify the presence or absence of cooling abnormalities and the location where the abnormality occurs during vehicle operation is desired. 【0004】 As an example of a cooling abnormality detection system, Patent Document 1 is cited here. Patent Document 1 discloses a technique for detecting the temperature of a heat-generating component, the temperature of a cooling component, and the power consumption of the heat-generating component, calculating the thermal resistance value of the contact portion between the heat-generating component and the cooling component, and detecting an abnormality in the contact portion between the heat-generating component and the cooling component based on the thermal resistance value. 【0005】 Japanese Unexamined Patent Application Publication No. 2016 - 72473 【0006】However, according to the technology described in Patent Document 1, abnormalities in the contact area between heat-generating components and cooling components can only be detected individually. Therefore, there is a problem in that it cannot detect abnormalities such as increased heat loss of semiconductor elements or decreased cooling efficiency due to fouling or deterioration of the cooler, which are common cooling abnormalities in power conversion devices. 【0007】 Furthermore, power converters for railway vehicles, for example, require multiple semiconductor modules to be arranged in series and parallel to handle multiphase AC, high current, and high voltage, resulting in a large number of modules. For this reason, a system capable of detecting abnormalities in the semiconductor modules and the heat dissipation paths for each phase, i.e., localized abnormalities, is desirable. 【0008】 Furthermore, in order to shorten the downtime and maintenance period of the equipment after a cooling anomaly occurs, a system that can detect cooling anomalies while the power converter is in operation and identify the location of the anomaly is desirable. 【0009】 Therefore, the present invention has been made in view of the above-mentioned problems, and aims to provide a technology that enables the detection of abnormalities in the semiconductor module, TIM, or cooler during the operation of a power conversion device, and the identification of the location where the abnormality occurred. 【0010】 To solve the above problems, one representative system for detecting cooling abnormalities in a power conversion device of the present invention comprises a power conversion device including a semiconductor module, a semiconductor module internal temperature detection unit, a cooler temperature detection unit, and a refrigerant temperature detection unit, and a calculation device that outputs an abnormality determination result for the power conversion device. The calculation device comprises a thermal resistance prediction unit that calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the refrigerant, based on the semiconductor module internal temperature history during actual operation, the cooler temperature history during actual operation, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation, and an abnormality determination unit that determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the refrigerant, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation. 【0011】According to the present invention, it is possible to detect a cooling abnormality in a power converter while the power converter is in operation, and to identify which semiconductor module or phase of the conversion circuit the abnormality occurred on the heat dissipation path, and further, whether it occurred in the semiconductor module, TIM, cooler, or refrigerant. Problems, configurations, and effects other than those described above will be clarified by the description of embodiments for carrying out the invention below. 【0012】 Figure 1 is a schematic diagram of an example of a system for detecting cooling abnormalities in a power converter for railway vehicles according to Example 1. Figure 2 is a diagram showing an example of the structure of a power converter for railway vehicles according to Example 1. Figure 3 is a block diagram of the system for detecting cooling abnormalities in a power converter for railway vehicles according to Example 1. Figure 4 is a diagram showing an example of the processing flow of the abnormality determination unit of the system for detecting cooling abnormalities in a power converter for railway vehicles according to Example 1. Figure 5 is a diagram showing an example of the structure of a power converter for railway vehicles according to Example 2. Figure 6 is a diagram showing an example of the structure of a power converter for railway vehicles according to Example 3. Figure 7 is a diagram showing an example of the structure of a power converter for railway vehicles according to Example 4. Figure 8 is a diagram showing an example of the processing flow of the abnormality determination unit of the system for detecting cooling abnormalities in a power converter for railway vehicles according to Example 4. 【0013】 Hereinafter, embodiments for carrying out the present invention will be described with reference to the figures. However, the present invention is not limited to these embodiments. Furthermore, in the drawings, identical parts are denoted by the same reference numerals. 【0014】 (Example 1) (System Configuration) First, Example 1 will be described. Figure 1 is a schematic diagram of an example of a system for detecting cooling abnormalities in a power converter for railway vehicles according to Example 1. Note that in Figure 1, components of the railway system that are not related to the present invention are omitted. 【0015】 Underneath the floor of the railway vehicle 1, a power converter 2, bogies 3, motors 4, transmission equipment 5, and vehicle information equipment 6 are installed. The computing device 12 may be installed on the vehicle side or in a separate location from the railway vehicle 1 (for example, on the ground side). 【0016】The power converter 2 supplies AC power 7 to the motor 4 installed on the trolley 3 to drive the motor 4. The power converter 2 also transmits the semiconductor module internal temperature history 8 (T1), the cooler temperature history 9 (T2), and the refrigerant temperature history 10 (T3) during actual operation to the transmission device 5. 【0017】 The vehicle information device 6 transmits the operational history 17 from actual operation to the transmission device 5. 【0018】 The transmission device 5 transmits the semiconductor module internal temperature history 8, the cooler temperature history 9, the refrigerant temperature history 10, and the operation history 17 during actual operation to the computing device 12. 【0019】 The computing device 12 outputs an abnormality determination result 11 and transmits it to the transmission device 5. The transmission device 5 transmits the abnormality determination result 11 to the driver or conductor inside the vehicle, or to a station or operation management center outside the vehicle. The computing device 12 is installed on the ground or on the vehicle. If it is installed on the ground, data between the computing device and the power converter is transmitted and received via the transmission device 5. On the other hand, if it is installed on the vehicle side, such as under the floor of the railway vehicle 1, the semiconductor module internal temperature history 8, the cooler temperature history 9, the refrigerant temperature history 10, and the operation history 17 during actual operation may be received directly by wire from the power converter 2 and the vehicle information device 6 without going through the transmission device 5. 【0020】 Furthermore, the operating temperature history 8 within the semiconductor module, the operating temperature history 9 of the cooler, and the operating temperature history 10 of the refrigerant may be transmitted to the transmission device 5 via the vehicle information device 6. Alternatively, the operating temperature history 10 of the refrigerant may be transmitted to the transmission device 5 without going through the power converter 2, for example, by transmitting the temperature history of the outside air taken into the passenger compartment air conditioning system of the vehicle 2. The transmission path is not limited. In addition, the power converter 2, the vehicle information device 6, and the transmission device 5 may be configured together as a single device. 【0021】(Power Conversion Device) Figure 2 shows an example of the structure of a power conversion device for a railway vehicle according to Embodiment 1. The power conversion device 2 has one or more semiconductor modules 31 (sometimes simply called modules) and a cooler. The semiconductor modules are installed on one side (also called the mounting surface) of the heat receiving block 32 of the cooler via a TIM (not shown). On the side of the heat receiving block 32 opposite to the mounting surface, cooling fins 33 are mounted as a cooling means by water cooling or air cooling, and are cooled by cooling air 34 from a fan or running airflow. Figure 2(a) is a perspective view of the semiconductor module 31 and the heat receiving block 32 from the direction normal to the mounting surface. Figure 2(b) is a perspective view of the semiconductor module 31, the heat receiving block 32 and the cooling fins 33 from a direction parallel to the mounting surface. 【0022】 Each semiconductor module 31 is equipped with a semiconductor module internal temperature detection unit 13 corresponding to the semiconductor module 31. Similarly, a cooler temperature detection unit 14 corresponding to each semiconductor module 31 is installed in the heat receiving block 32. A refrigerant temperature detection unit 15 is also installed near the cooling fins 33. The semiconductor module internal temperature detection unit 13 is provided, for example, on the heat dissipation base or insulating substrate of the semiconductor module 31. When there are multiple semiconductor modules, it is desirable that there be modules with a similar distance relationship between the semiconductor module internal temperature detection unit 13 and the cooler temperature detection unit 14, which are provided for the same semiconductor module. In this case, the distance relationship between the heat-generating points of each module and the semiconductor module internal temperature detection unit 13 and the cooler temperature detection unit 14 will be the same, so the temperature and thermal resistance of each module can be compared side by side, and the amount of computation required for abnormality detection can be reduced. Alternatively, a cooler temperature detection unit 14 that corresponds to different semiconductor modules 31 may be provided in common. 【0023】The refrigerant temperature detection unit 15 is installed, for example, near or on the cooling fins. Alternatively, it may refer to the inlet air temperature of other devices installed in the vehicle, such as the inlet air temperature for the passenger compartment air conditioning, or weather data. Here, if multiple rows of modules are installed in the direction of the cooling airflow 34, a refrigerant temperature detection unit 15 corresponding to each module row may be provided in order to obtain the refrigerant temperature history 10 (T3) during actual operation of each module row. Alternatively, the refrigerant temperature detection unit 15 may be provided only on the upwind side, and the refrigerant temperature history 10 (T3) during actual operation of the other rows may be estimated from the heat generation history 18 (P) of the semiconductor modules during actual operation and the refrigerant flow rate. 【0024】 For the temperature detection units 13 to 15, for example, thermistors and thermocouples may be used. In addition, methods for installing the temperature detection units may include soldering, fixing with adhesive or tape, or embedding them in the heat dissipation base of the semiconductor module 31 or in holes or grooves in the heat receiving block. 【0025】 (System Block Configuration and Processing Flow) Figure 3 is a block diagram of a system for detecting cooling abnormalities in a power converter for railway vehicles according to Embodiment 1. Some components have been omitted. 【0026】 The power converter 2 is equipped with a semiconductor module internal temperature detection unit 13, a cooler temperature detection unit 14, and a refrigerant temperature detection unit 15. These units acquire the semiconductor module internal temperature history 8 (T1), the cooler temperature history 9 (T2), and the refrigerant temperature history 10 (T3) during actual operation, respectively, and transmit them to the computing unit 12 via the transmission device 5. The vehicle information device 6 also acquires the operation history 17 during actual operation and transmits it to the computing unit 12 via the transmission device 5. 【0027】The computing unit 12 has a heat generation prediction unit and calculates the heat generation history 18(P) of the semiconductor module during actual operation based on the operation history 17 during actual operation. The computing unit 12 also has a thermal resistance prediction unit and calculates the thermal resistance 19(R12) between the semiconductor module and the cooler, and the thermal resistance 20(R23) between the cooler and the cooler, based on the internal semiconductor module temperature history 8(T1) during actual operation, the cooler temperature history 9(T2) during actual operation, the refrigerant temperature history 10(T3) during actual operation, and the heat generation history 18(P) of the semiconductor module during actual operation. The thermal resistance is predicted, for example, using the following equations (1) and (2). Based on these calculation results, the abnormality detection unit 21 performs an abnormality detection and identifies the location of the abnormality, and transmits the abnormality detection result 11 to the transmission device 5. 【0028】 The processing cycle in the arithmetic unit 12 is assumed to be a processing cycle that is executed at intervals of a certain amount of time, such as once a month, or once every three or six months. 【0029】 Figure 4 shows an example of the processing flow of the abnormality determination unit of the system for detecting cooling abnormalities in a power converter for railway vehicles according to Embodiment 1. The abnormality determination unit 21 determines the location of the abnormality based on the thermal resistance 19 (R12) between the semiconductor module and the cooler, the thermal resistance 20 (R23) between the cooler and the refrigerant, the semiconductor module internal temperature history 8 (T1) during actual operation, the cooler temperature history 9 (T2) during actual operation, the refrigerant temperature history 10 (T3) during actual operation, and the heat generation history 18 (P) of the semiconductor module during actual operation. In this determination, threshold values ​​are set for the thermal resistance R12, R23, temperature T3, and heat generation P to maintain the semiconductor element temperature below an acceptable value. The following describes the processing steps. 【0030】 S401: Determine whether the thermal resistance 20 (R23) between the cooler and the refrigerant is "R23 > thermal resistance threshold". If Yes, output abnormal mode 1: cooler abnormality and terminate processing. If No, proceed to S402. 【0031】S402: Determine whether the thermal resistance 19 (R12) between the semiconductor module and the cooler is "R12 > thermal resistance threshold". If Yes, output abnormal mode 2: TIM abnormality and terminate processing. If No, proceed to S403. 【0032】 S403: Determine whether the heat generation history 18(P) of the semiconductor module during actual operation is "P > heat generation threshold". If Yes, output abnormal mode 3: abnormal heat loss of the semiconductor module and terminate processing. If No, proceed to S404. 【0033】 S404: Determine whether the refrigerant temperature history 10 (T3) during actual operation is "T3 > temperature threshold". If Yes, output abnormal mode 4: abnormal refrigerant temperature and terminate processing. If No, proceed to S405. 【0034】 S405: Abnormal Mode 5: Outputs other abnormalities and terminates processing. 【0035】 The following provides further details on each abnormal mode. Abnormal Mode 1, a malfunction of the cooler, may be due to a decrease in cooling efficiency caused by fouling, damage, or deterioration of the cooler. Specifically, in the case of an air-cooled system, this could include fouling or clogging of the fins or fin cover due to dust around the vehicle, or damage caused by flying objects. In the case of a water-cooled system, this could include deterioration of the refrigerant, or dirt and corrosion of the heat sink. 【0036】 An abnormality in TIM mode 2 could be an increase in contact thermal resistance between the semiconductor module and the cooler due to TIM degradation. Specific phenomena could include, for example, deterioration of the TIM's thermal conductivity due to repeated thermal cycling, the formation of cracks or voids within the TIM, hardening of the TIM leading to decreased adhesion of the contact surface, and a pump-out phenomenon. 【0037】 Abnormal Mode 3 in semiconductor modules can be attributed to the deterioration of internal components. Specific phenomena include deterioration of terminals and nodes, corrosion, increased contact resistance due to oxidation, increased internal resistance of semiconductor elements and wiring, and reduced performance due to deterioration of materials and structures within semiconductor elements. 【0038】Abnormal Mode 4 can indicate an abnormality in refrigerant temperature, specifically overheating of the refrigerant. Possible causes include the influence of weather conditions, abnormal heat generation from nearby equipment, and deterioration or failure of cooling fans or pumps. 【0039】 Other abnormalities in abnormal mode 5 include, for example, abnormal temperature detection values. Specific phenomena could include failure or delamination of the temperature detection unit. 【0040】 Note that the order of the processing flow in Figure 4 is just one example, and the order of the flow may be changed depending on the frequency of abnormal mode occurrences, the driving area, and the characteristics of the vehicle. 【0041】 Furthermore, while we have described the case where the temperature input value to the arithmetic unit 12 is obtained from the actual operating semiconductor module internal temperature history 8 (T1), the actual operating cooler temperature history 9 (T2), and the actual operating refrigerant temperature history 10 (T3), for example, data from the time when the maximum value of the semiconductor module internal temperature, cooler temperature, refrigerant temperature, or heat generation of the semiconductor module was recorded may also be used. Alternatively, data close to the heat generation amount and temperature conditions when the temperature threshold or thermal resistance threshold was defined may be extracted and used. This makes it possible to reduce the amount of data transmitted from the transmission device 5 to the arithmetic unit 12 and to reduce the amount of calculation. 【0042】 Finally, the effects of Example 1 will be explained. According to Example 1, abnormalities in the semiconductor module, TIM, and cooler can be detected while the railway vehicle is in operation, and it is possible to identify whether the abnormality occurred in the semiconductor module, TIM, cooler, or refrigerant. Furthermore, by providing temperature detection units that correspond to multiple mounted modules, it is possible to identify which semiconductor module's heat dissipation path is experiencing the abnormality. As a result, tests to identify the location of the abnormality become unnecessary, thus shortening the downtime and maintenance period of the equipment. 【0043】(Example 2) Next, the differences between Example 2 and Example 1 will be mainly described. FIG. 5 is a diagram showing an example of the structure of a power conversion device for a railway vehicle according to Example 2. A plurality of semiconductor modules 41, 42, 43 are provided on the installation surface of the heat receiving block 32, and cooling fins 33 are provided on the opposite surface thereof. The short side direction of the semiconductor modules 41, 42, 43 is arranged facing the direction parallel to the cooling air, and they are arranged in a plurality of stages in the refrigerant flow direction and the orthogonal direction. The plurality of semiconductor modules (for example, 41a, 41b, 41c) arranged in the refrigerant flow direction constitute one phase of the conversion circuit. FIG. 5(a) is a diagram showing the semiconductor modules 41, 42, 43 and the heat receiving block 32 in a perspective top view from the normal direction of the installation surface. Further, FIG. 5(b) is a diagram showing the semiconductor modules 41, 42, 43, the heat receiving block 32, and the cooling fins 33 in a perspective top view from the short side direction parallel to the installation surface. Further, in correspondence with each phase of the conversion circuit, cooler temperature detection units 44, 45, 46 are arranged on the heat receiving block 32. 【0044】 The arithmetic unit 12 predicts the thermal resistance 19 (R12) between the semiconductor module and the cooler and the thermal resistance 20 (R23) between the cooler and the refrigerant in the arithmetic unit 12 for each phase of the conversion circuit based on the in-operation semiconductor module internal temperature history 8 (T1a, T1b, T1c), the in-operation cooler temperature history 9 (T2), the in-operation refrigerant temperature history 10 (T3), and the in-operation heat generation amount history 18 (P) of the semiconductor module. The prediction formula for the thermal resistance 19 (R12) between the semiconductor module and the cooler is, for example, for the phase of the semiconductor module 41 (41a, 41b, 41c), based on the in-operation semiconductor module internal temperature history 8 (T1a, T1b, T1c), the in-operation cooler temperature history 9 (T2) at the cooler temperature detection unit 44, and the in-operation heat generation amount history 18 (P1) of the semiconductor module 41, it is performed using the following formulas (3) to (5). Here, the subscripts a, b, c indicate each semiconductor module in the cooling air direction. 【0045】In the abnormality determination unit 21, threshold values for each phase of the converter for maintaining the semiconductor element temperature below the allowable value are set for the thermal resistances R12, R23, and T2. Other procedures for abnormality determination are the same as those in the first embodiment. 【0046】 Among the abnormal modes, abnormal mode 1 and abnormal mode 2 enable detection of abnormalities in each phase of the converter. Other abnormal modes are the same as those in the first embodiment. 【0047】 According to the method according to the second embodiment, when a large number of semiconductor modules are mounted such that a plurality of modules are connected in parallel to obtain a high current or high voltage and a multiphase alternating current is realized, it is possible to detect abnormalities in each semiconductor module and abnormalities in the TIM and cooler in each phase unit. When variations in TIM and cooler deterioration occur between phases due to factors such as current imbalance, or when cooler damage varies in the height direction due to factors such as ballast collision, it is a configuration that is easy to detect abnormalities. Also, by reducing the number of cooler temperature detection parts, cost reduction can be achieved. 【0048】 (Third Embodiment) Next, differences from the first embodiment in the third embodiment will be mainly described. FIG. 6 is a diagram showing an example of the structure of a power conversion device for a railway vehicle according to the third embodiment. A plurality of semiconductor modules 41, 42, and 43 are provided on the ground plane of the heat receiving block 32, and cooling fins 33 are provided on the opposite surface thereof. The longitudinal directions of the semiconductor modules 41, 42, and 43 are arranged facing the direction parallel to the cooling air, and are arranged in a plurality of stages in the refrigerant flow direction and the orthogonal direction. A plurality of semiconductor modules (for example, 41a, 41b, 41c) arranged in the direction orthogonal to the refrigerant flow direction constitute one phase of the conversion circuit. FIG. 6(a) is a diagram showing a perspective overhead view of the semiconductor modules 41, 42, and 43 and the heat receiving block 32 from the normal direction of the installation surface. Also, FIG. 6(b) is a diagram showing a perspective overhead view of the semiconductor modules 41, 42, and 43, the heat receiving block 32, and the cooling fins 33 from the longitudinal direction parallel to the installation surface. Further, cooler temperature detection parts 44, 45, and 46 are arranged on the heat receiving block 32 so as to correspond to each phase of the conversion circuit. 【0049】The calculation of thermal resistance in the arithmetic unit 12, the thermal resistance and temperature thresholds for the abnormality determination 21, and the concept of abnormality modes are the same as in Example 2. 【0050】 The method according to this embodiment 3 makes it possible to detect abnormalities in each semiconductor module, as well as abnormalities in the TIM and cooler on a phase-by-phase basis, when multiple semiconductor modules are connected in parallel to achieve multiphase AC in order to obtain high current and high voltage, and when a large number of semiconductor modules are installed. This configuration makes it easy to detect abnormalities when there are variations in the deterioration of the TIM and cooler between phases due to factors such as current imbalance, or when the deterioration of the cooler varies in the direction of the cooling air due to factors such as fin fouling and clogging. In addition, costs can be reduced by reducing the number of points in the cooler temperature detection unit. 【0051】 (Example 4) Next, Example 4 will be described, focusing on the differences from Example 1. Figure 7 shows an example of the structure of a power converter for railway vehicles according to Example 4. Multiple semiconductor modules 51 are arranged on a heat receiving block 32. The semiconductor module 51 is a 2-in-1 module, and two sets of parallel-connected semiconductor elements 52 (such as IGBTs or MOSFETs and diodes) are connected in series in one module. Here, the sets of parallel-connected semiconductor elements 52 are called arms 53, and each can be energized independently. In addition, the semiconductor module internal temperature detection units 54a, 54b, 54c (T1a, T1b, T1c), which are installed corresponding to each semiconductor module 51a, 51b, 51c, are arranged asymmetrically with respect to the two arms 53 in the semiconductor module 51. In the following description, the direction of the arrangement of the arms 53 in the semiconductor module 51 will be referred to as direction 61, and the direction perpendicular to the arrangement of the arms will be referred to as direction 62. Furthermore, within the semiconductor modules 51a, 51b, and 51c, the arms closer to the temperature detection unit 54 are designated 53e, 53g, and 53i, and the arms further away are designated 53f, 53h, and 53j. Figure 7(a) is a perspective view of the semiconductor module 51 and the heat receiving block 32 from the direction normal to the installation surface. Figure 7(b) is a perspective view of the semiconductor module 51, the heat receiving block 32, and the cooling fins 33 from the short side parallel to the installation surface. 【0052】First cooler temperature detection units 55a, 55b, 55c (T2a, T2b, T2c) are arranged on the heat receiving block 32 to correspond to each row of semiconductor modules 51 in direction 62. A second cooler temperature detection unit 56 (T2d) is also arranged to correspond to each row of semiconductor modules 51 in direction 61. Here, the second cooler temperature detection unit 56 is located near the arm 53j, which is at the end of the arrangement of semiconductor modules 51 in direction 61. 【0053】 As shown in Figure 7, with respect to the arm 53 (53g, 53i) closer to the semiconductor module internal temperature detection units 54b, 54c, it is assumed that the distance relationship between the semiconductor module internal temperature detection units 54b, 54c corresponding to the semiconductor module (referred to as the self-semiconductor module) 51b, 51c to which the arm belongs and the cooler temperature detection units 55b, 55c corresponding to the self-semiconductor module is equivalent to the distance relationship between the cooler temperature detection units 55a, 55b corresponding to the semiconductor modules adjacent to the self-semiconductor module (referred to as adjacent semiconductor modules) 51a, 51b. In this case, with respect to the thermal resistance 19 (R12) between the semiconductor module and the cooler, it is estimated that the values ​​R12bbg and R12cci obtained from the temperature history (T1b and T1c) of the semiconductor module internal temperature detection units 54b and 54c of the semiconductor modules 51b and 51c, along with the temperature history (T2b and T2c) of the cooler temperature detection units 55b and 55c installed in correspondence with the semiconductor modules 51b and 51c, are equivalent to the values ​​R12abg and R12bci obtained from the temperature history (T2a and T2b) of the cooler temperature detection units 55a and 55b installed in correspondence with the adjacent semiconductor modules 51a and 51b. Therefore, either or both of these values ​​can be used as an abnormality indicator for the TIM of the arm 53 (53g and 53i). 【0054】Similarly, with respect to the arms 53 (53f, 53h, 53j) that are farther from the semiconductor module internal temperature detection units 54a, 54b, 54c, it is assumed that the distance relationship between the semiconductor module internal temperature detection units 54a, 54b, 54c corresponding to the semiconductor module 51a, 51b, 51c and the cooler temperature detection units 55a, 55b, 55c corresponding to the semiconductor module 51a, 51b, 51c is equivalent to the distance relationship between the semiconductor module internal temperature detection units 54b, 54c corresponding to the adjacent semiconductor module 51b, 51c, or the second cooler temperature detection unit 56. In this case, with respect to the thermal resistance 19 (R12) between the semiconductor module and the cooler, the values ​​R12aaf, R12bbh, R12ccj obtained by combining the temperature history (T2a, T2b, T2c) of the cooler temperature detection units 55a, 55b, 55c corresponding to the semiconductor modules 51a, 51b, 51c with the temperature history (T1a, T1b, T1c) of the semiconductor module internal temperature detection units 54a, 54b, 54c corresponding to the semiconductor modules 51a, 51b, 51c, and the values ​​R12abf, R12bch, R12cdj obtained by combining the temperature history (T1b, T1c, T2d) of the semiconductor module internal temperature detection unit 54b, 54c or the second cooler temperature detection unit 56 corresponding to the adjacent semiconductor module are estimated to be equivalent. Therefore, both or either of these can be used as an abnormality indicator for the TIM of the arm 53 (53f, 53h, 53j). 【0055】 The calculation unit 12 performs the prediction of the heat generation history P and the thermal resistance 19 (R12) between the semiconductor module and the cooler for each arm 53 (53e to 53j). The prediction of the thermal resistance 19 (R12) between the semiconductor module and the cooler is performed, for example, using equations (6) to (11) shown in Table 1 below. Here, the subscripts a, b, and c indicate the column of each semiconductor module in direction 62, and the subscripts e to j indicate the column of each arm in direction 62. For example, for arm 53f, the thermal resistance 19 (R12) between the semiconductor module and the cooler can be obtained as an indicator for determining abnormalities not only from the temperature history of the semiconductor module internal temperature detection unit 54a (T1a) and the first cooler temperature detection unit 55a (T2a) as shown in equation (7-1), but also from the temperature history of the semiconductor module internal temperature detection unit 54b (T1b) and the first cooler temperature detection unit 55a (T2a) as shown in equation (7-2). 【0056】 Figure 8 shows an example of the processing flow of the abnormality determination unit of the system for detecting cooling abnormalities in a power converter for railway vehicles according to Embodiment 4. In the abnormality determination unit 21, threshold values ​​are set for each arm 53 for thermal resistance R12 (S402-1 to S402-6) and heat generation amount P (S403). The other abnormality determination procedures are the same as in Embodiment 1. 【0057】 Of the abnormal modes, abnormal modes 2 and 3 enable abnormality detection on an arm-by-arm basis. The other abnormal modes are the same as in Example 1. 【0058】 As described above, according to the method of Embodiment 4, when each arm is energized independently within the same semiconductor module, such as a 2-in-1 module, it is possible to detect abnormalities in each semiconductor module, as well as abnormalities in TIM and heat loss on an arm-by-arm basis. 【0059】 In this embodiment, in order to estimate the thermal resistance of each arm, we considered using a second cooler temperature detection unit 56 to simulate the semiconductor module internal temperature detection unit. However, since the thermal resistance is estimated from the temperatures of the coolers, there is a concern that the temperature difference will be small and the estimation accuracy of the thermal resistance R12cdj will be low. For this reason, it is desirable to install the second cooler temperature detection unit 56 as close to the semiconductor module as possible. For example, a groove can be provided on the contact surface of the cooler with the semiconductor module, and the unit can be installed directly below or near the arm 53j. In addition, in this embodiment, we assumed that there is only one semiconductor module internal temperature detection unit asymmetrically arranged for the two arms 53 in the semiconductor module 51, but the semiconductor module 51c may be replaced with a module that has a semiconductor module internal temperature detection unit corresponding to each of the two arms 53. This makes it possible to obtain the same effect as in Embodiment 4 while maintaining the same thermal resistance estimation accuracy as in Embodiment 1. 【0060】The present invention is not limited to the embodiments described above, and other forms conceivable within the scope of the technical concept of the present invention are also included within the scope of the present invention, as long as they do not impair the features of the present invention. For example, the application of the power conversion device is not limited to railway vehicles, but can be applied to power conversion used in other applications such as automobiles, aircraft, and ships. 【0061】The following describes embodiments that may constitute the content of the present invention, but are not limited thereto. (Embodiment 1) A system for detecting a cooling abnormality in a power converter, comprising: a power converter including a semiconductor module, a semiconductor module internal temperature detection unit, a cooler temperature detection unit, and a refrigerant temperature detection unit; and a calculation device that outputs an abnormality determination result for the power converter, wherein the calculation device comprises: a thermal resistance prediction unit that calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the refrigerant based on the semiconductor module internal temperature history during actual operation, the cooler temperature history during actual operation, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit that determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the refrigerant, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation, characterized in that the system for detecting a cooling abnormality in a power converter. (Aspect 2) A system for detecting a cooling abnormality in a power converter according to Aspect 1, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit corresponding to each of the plurality of semiconductor modules are installed, and the distance relationship between the semiconductor module internal temperature detection unit and the cooler temperature detection unit corresponding to the same semiconductor module includes those among the plurality of semiconductor modules that have an equivalent relationship. (Aspect 3) A system for detecting a cooling abnormality in a power converter according to Aspect 1 or 2, wherein a heat receiving block having a plurality of semiconductor modules on one side and cooling fins provided on the opposite side of the heat receiving block are provided, the short side of the semiconductor modules are arranged in a direction parallel to the direction of cooling airflow, the plurality of semiconductor modules are arranged in multiple stages in directions parallel to and perpendicular to the direction of cooling airflow, the plurality of semiconductor modules arranged parallel to the direction of cooling airflow constitute one phase of a conversion circuit, and the heat receiving block is provided with a cooler temperature detection unit corresponding to each phase of the conversion circuit.(Aspect 4) A system for detecting a cooling abnormality in a power converter according to aspect 1 or 2, comprising: a heat receiving block having a plurality of semiconductor modules on one side; and cooling fins provided on the opposite side of the heat receiving block; the longitudinal direction of the semiconductor modules is oriented parallel to the direction of cooling airflow; the plurality of semiconductor modules are arranged in multiple stages in directions parallel and perpendicular to the direction of cooling airflow; the plurality of semiconductor modules arranged in directions perpendicular to the direction of cooling airflow constitute one phase of a conversion circuit; and the heat receiving block is provided with a cooler temperature detection unit corresponding to each phase of the conversion circuit. (Aspect 5) A system for detecting a cooling abnormality in a power converter according to any one of aspects 1 to 4, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit corresponding to each of a plurality of semiconductor modules are installed, the semiconductor module includes a plurality of arms, the computing unit outputs an abnormality determination result for each arm, and with respect to the arm closest to the semiconductor module internal temperature detection unit corresponding to the semiconductor module to which the arm belongs (referred to as the self-semiconductor module), the distance relationship between the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module and the cooler temperature detection unit corresponding to the self-semiconductor module is the same as the distance relationship between the cooler temperature detection unit corresponding to the semiconductor module adjacent to the self-semiconductor module (referred to as the adjacent semiconductor module), characterized in that, with respect to the arm closest to the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module, the distance relationship between the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module and the cooler temperature detection unit corresponding to the self-semiconductor module is the same.(Aspect 6) A system for detecting a cooling abnormality in a power converter according to any one of aspects 1 to 5, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit corresponding to each of a plurality of semiconductor modules are installed, the semiconductor module includes a plurality of arms, the computing unit outputs an abnormality determination result for each arm, and with respect to the arm furthest from the semiconductor module internal temperature detection unit corresponding to the semiconductor module to which the arm belongs (referred to as the self-semiconductor module), the distance relationship between the self-semiconductor module internal temperature detection unit and the cooler temperature detection unit corresponding to the self-semiconductor module is the same as the distance relationship between the semiconductor module internal temperature detection unit corresponding to the semiconductor module adjacent to the self-semiconductor module (referred to as the adjacent semiconductor module), characterized in that, with respect to the arm furthest from the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module, the distance relationship between the self-semiconductor module internal temperature detection unit and the semiconductor module internal temperature detection unit corresponding to the adjacent semiconductor module is the same. (Aspect 7) A system for detecting a cooling abnormality in a power converter according to any one of aspects 1 to 6, wherein the computing unit determines a cooling abnormality based on data of the time when the semiconductor module internal temperature, cooler temperature, refrigerant temperature, or heat generation amount of the semiconductor module recorded its maximum value, characterized in that, (Aspect 8) A system for detecting a cooling abnormality in a power converter according to any one of aspects 1 to 7, wherein the computing device is installed on the ground side or on the vehicle side, and if installed on the ground side, it comprises a transmission device for sending and receiving data between the computing device and the power converter. (Aspect 9) A computing device for outputting an abnormality determination result for a power converter, comprising: a thermal resistance prediction unit that calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the cooler, based on the semiconductor module's internal temperature history during actual operation, the cooler's temperature history during actual operation, the cooler's temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit that determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the cooler, the cooler's temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation.(Aspect 10) A method for detecting a cooling abnormality in a power converter, characterized in that a thermal resistance prediction unit calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the cooler, based on the temperature history inside the semiconductor module during actual operation, the temperature history of the cooler during actual operation, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the cooler, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation. 【0062】 1...Railway vehicle 2...Power converter 3...Bogie 4...Motor 5...Transmission device 6...Vehicle information device 7...AC power 8...Temperature history inside semiconductor module during actual operation (T1) 9...Cooler temperature history during actual operation (T2) 10...Refrigerant temperature history during actual operation (T3) 11...Anomaly detection result 12...Calculation unit 13...Temperature detection unit inside semiconductor module (T1) 14...Cooler temperature detection unit (T2) 15...Refrigerant temperature detection unit (T3) 16...Anomaly detection system 17...Operation history during actual operation 18...Heat generation history of semiconductor module during actual operation (P) 19...Thermal resistance between semiconductor module and cooler (R12) 20...Thermal resistance between cooler and refrigerant (R23) 21...Anomaly detection unit 31...Semiconductor module 32...Heat receiving block 33...Cooling fin 34...Cooling air 41, 42, 43...Semiconductor module 44, 45, 46... Cooler temperature detection unit (T2) 51... Semiconductor module 52... Semiconductor element 53... Arm 54... Semiconductor module internal temperature detection unit (T1a, T1b, T1c) 55... First cooler temperature detection unit (T2a, T2b, T2c) 56... Second cooler temperature detection unit (T2d) 61... Arrangement direction of the arms 53 in the semiconductor module 51 62... Direction perpendicular to the arrangement direction of the arms 53 in the semiconductor module 51

Claims

1. A system for detecting a cooling abnormality in a power converter, comprising: a power converter including a semiconductor module, a semiconductor module internal temperature detection unit, a cooler temperature detection unit, and a refrigerant temperature detection unit; and a computing device that outputs an abnormality determination result for the power converter, wherein the computing device comprises: a thermal resistance prediction unit that calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the refrigerant based on the semiconductor module internal temperature history during actual operation, the cooler temperature history during actual operation, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit that determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the refrigerant, the refrigerant temperature history during actual operation, and the heat generation history of the semiconductor module during actual operation.

2. A system for detecting a cooling abnormality in a power converter according to claim 1, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit corresponding to each of the plurality of semiconductor modules are installed, and the distance relationship between the semiconductor module internal temperature detection unit and the cooler temperature detection unit corresponding to the same semiconductor module includes those among the plurality of semiconductor modules that have an equivalent relationship.

3. A system for detecting a cooling abnormality in a power converter according to claim 1, comprising: a heat receiving block having a plurality of semiconductor modules on one side; and cooling fins provided on the opposite side of the heat receiving block; the semiconductor modules are arranged so that their short sides are parallel to the direction of cooling airflow; the plurality of semiconductor modules are arranged in multiple stages in directions parallel and perpendicular to the direction of cooling airflow; the plurality of semiconductor modules arranged parallel to the direction of cooling airflow constitute one phase of a conversion circuit; and the heat receiving block is provided with a cooler temperature detection unit corresponding to each phase of the conversion circuit.

4. A system for detecting a cooling abnormality in a power converter according to claim 1, comprising: a heat receiving block having a plurality of semiconductor modules on one side; and cooling fins provided on the opposite side of the heat receiving block; the longitudinal direction of the semiconductor modules is oriented parallel to the direction of cooling airflow; the plurality of semiconductor modules are arranged in multiple stages in directions parallel and perpendicular to the direction of cooling airflow; the plurality of semiconductor modules arranged perpendicular to the direction of cooling airflow constitute one phase of a conversion circuit; and the heat receiving block is provided with a cooler temperature detection unit corresponding to each phase of the conversion circuit.

5. A system for detecting a cooling abnormality in a power converter according to claim 1, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit are installed corresponding to each of a plurality of semiconductor modules, the semiconductor module includes a plurality of arms, the computing unit outputs an abnormality determination result for each arm, and with respect to the arm closest to the semiconductor module internal temperature detection unit corresponding to the semiconductor module to which the arm belongs (referred to as the self-semiconductor module), the distance relationship between the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module and the cooler temperature detection unit corresponding to the self-semiconductor module is the same as the distance relationship between the cooler temperature detection unit corresponding to the semiconductor module adjacent to the self-semiconductor module (referred to as the adjacent semiconductor module), characterized in that, with respect to the arm closest to the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module, the distance relationship between the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module and the cooler temperature detection unit corresponding to the adjacent semiconductor module is the same.

6. A system for detecting a cooling abnormality in a power converter according to claim 1, wherein a semiconductor module internal temperature detection unit and a cooler temperature detection unit are provided for each of a plurality of semiconductor modules, the semiconductor module includes a plurality of arms, the computing unit outputs an abnormality determination result for each arm, and with respect to the arm furthest from the semiconductor module internal temperature detection unit corresponding to the semiconductor module to which the arm belongs (referred to as the self-semiconductor module), the distance relationship between the cooler temperature detection unit corresponding to the self-semiconductor module and the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module is equivalent to the distance relationship between the semiconductor module internal temperature detection unit corresponding to the semiconductor module adjacent to the self-semiconductor module (referred to as the adjacent semiconductor module), characterized in that, with respect to the arm furthest from the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module, the distance relationship between the semiconductor module internal temperature detection unit corresponding to the self-semiconductor module and the cooler temperature detection unit corresponding to the self-semiconductor module is equivalent.

7. A system for detecting a cooling abnormality in a power converter according to any one of claims 1 to 6, wherein the computing device determines the cooling abnormality based on data of the time when the temperature inside the semiconductor module, the cooler temperature, the refrigerant temperature, or the amount of heat generated by the semiconductor module recorded its maximum value.

8. A system for detecting a cooling abnormality in a power converter according to any one of claims 1 to 6, wherein the computing device is installed on the ground side or on the vehicle side, and if installed on the ground side, it comprises a transmission device for sending and receiving data between the computing device and the power converter.

9. A calculation device for outputting an abnormality determination result for a power converter, comprising: a thermal resistance prediction unit that calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the cooler, based on the temperature history inside the semiconductor module during actual operation, the temperature history of the cooler during actual operation, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit that determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the cooler, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation, wherein the calculation device for outputting a cooling abnormality for a power converter is characterized by comprising:

10. A method for detecting a cooling abnormality in a power converter, characterized in that a thermal resistance prediction unit calculates the thermal resistance between the semiconductor module and the cooler, and the thermal resistance between the cooler and the cooler, based on the temperature history inside the semiconductor module during actual operation, the temperature history of the cooler during actual operation, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation; and an abnormality determination unit determines a cooling abnormality based on at least the thermal resistance between the semiconductor module and the cooler, the thermal resistance between the cooler and the cooler, the temperature history of the cooler during actual operation, and the heat generation history of the semiconductor module during actual operation.

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