KR20230076262A - Apparatus and method for detecting of inverter current sensor fault - Google Patents

Abstract

One embodiment of the present invention provides an inverter current sensor fault recognition device which comprises: a measuring unit (210) that measures three-phase currents (ia, ib, ic) and checks effectiveness; a conversion unit (220) that converts a current between individual phases among the three-phase currents into a stationary coordinate system α-β axis current, respectively; a calculation unit (230) that calculates a difference between a maximum value and a minimum value of a size for each converted current vector; a detection unit (240) that detects a malfunction sensor by comparison of the calculated difference between the maximum value and the minimum value; and a reflux unit (250) that feeds back a current error in consideration of the detected malfunction sensor.

Description

Inverter current sensor fault recognition device and method {APPARATUS AND METHOD FOR DETECTING OF INVERTER CURRENT SENSOR FAULT}

The present invention relates to an inverter current sensor fault recognition apparatus and method, and more particularly, to an apparatus and method capable of recognizing which phase current sensor has a fault by sensing three-phase current values.

Due to the finiteness of petroleum resources and the emergence of environmental problems, conventional internal combustion engine vehicles are rapidly being replaced by electric vehicles. Compared to conventional vehicles that generate driving force through conventional internal combustion engines, electric vehicles have an electric motor-based drive system. Currently, the importance of functional safety according to the ISO26262 standard for electric vehicles is increasing. ISO26262 is an automobile standard established to prevent accidents caused by errors in electronic/electrical systems. There are two major safety goals. That is, unintended acceleration of the electric vehicle must be prohibited, and high voltage of the motor controller (inverter) must be actively/passively discharged in case of an emergency.

Today, three-phase PWM inverters are widely used in various industrial fields, such as variable speed motor control, uninterruptible power supplies, and active power filters. PWM inverters usually control the torque of a motor or control the electricity to a power supply. For this, stable current control is essential. In order to control the current, a loop control system is created through a current sensor. However, the failure of the current sensor and the circuit related to the sensor creates a big problem in the stability of the current control. This can generate a large vibration torque in the motor and a device that controls power can affect the output voltage, so countermeasures against faults in the current sensor are needed for products requiring high reliability.

Prior literature: Korean Patent Publication 10-2017-0090149

The prior art document relates to an inverter failure diagnosis method and apparatus, which detects open failure of a switch in real time using current signals of each phase, which are signals used in an existing main controller, without using additional hardware elements in a 3-phase PWM inverter. It relates to an inverter failure diagnosis method and device capable of detecting and identifying a failure switch. In the prior literature, the step of measuring the three-phase current through the measuring unit, the step of converting the measured three-phase current into the stationary coordinate system axis current, the step of calculating the vector phase angle from the converted current, the step of calculating the vector phase angle based on the sector A method for diagnosing faults in an inverter, including dividing sections, generating fault detection variables based on the divided sector sections, and comparing the generated fault detection variables with a first threshold to determine whether an inverter is faulty. are initiating.

As such, various methods for detecting a failure of an inverter by measuring three-phase current have been proposed.

An object of one embodiment of the present invention is to provide an inverter current sensor fault recognition device and method capable of sensing each of the three-phase currents driving a three-phase motor and detecting which phase has an error.

In one embodiment of the present invention, the measurement unit 210 for measuring and checking the validity of the three-phase currents (ia, ib, ic), and the current between each phase of the three-phase current, respectively, the stationary coordinate system α-β axis current The conversion unit 220 converts to , the calculation unit 230 calculates the difference between the maximum value and the minimum value of the magnitude for each of the converted current vectors, and compares the difference between the calculated maximum value and minimum value. It is possible to provide an inverter current sensor fault recognition device including a detection unit 240 that detects a sensor and a feedback unit 250 that feeds back a current error in consideration of the detected fault sensor.

In the measurement unit, it is possible to examine whether the sensor values of each of the three-phase currents and the sum of the three-phase currents respectively correspond to a normal region.

The detection unit may find a difference between the calculated maximum value and minimum value of each of the converted current vectors is the minimum.

Another embodiment of the present invention is the step of measuring and checking the validity of the three-phase currents (ia, ib, ic), and converting the current between each phase among the three-phase currents into α-β axis currents in the stationary coordinate system, respectively. a calculation step of calculating a difference between the maximum and minimum values of magnitude for each of the converted current vectors; a detection step of detecting a faulty sensor by comparing the difference between the calculated maximum and minimum values; It is possible to provide an inverter current sensor fault recognition method including a feedback step of feeding back a current error in consideration of a fault sensor.

According to one embodiment of the present invention, it is possible to obtain an inverter current sensor fault recognition device and method capable of sensing each of the three-phase currents driving the three-phase motor and detecting which phase has an error. Through this, it isolates the faulted current sensor and enables fault tolerant operation in inverters and three-phase power conversion systems, and normal operation is possible up to 100% when an error occurs in the current sensor only in one phase. In addition, when calculating the fault value of the current sensor value, it is determined only by the three-phase current sensor value. It is a robust method that is not affected by other external sensors (voltage sensor, rotor position sensor) at all.

1 is a diagram showing a basic scheme for recognizing a fault of a current sensor in an electric vehicle.
2 is a block diagram of an inverter current sensor fault recognition device according to an embodiment of the present invention.
FIG. 3 is a graph showing the sensing values of currents measured when each of the three-phase currents are sensed and converted into α-β-axis currents.
4 shows a method of calculating the difference between the maximum value and the minimum value of magnitude for each current vector.
5 is a diagram illustrating a process performed in a detection unit of an inverter current sensor fault recognition device according to an embodiment of the present invention.
6 is a graph showing that an error occurs in a b-phase current sensor among three-phase current sensors in the inverter current sensor fault recognition device according to an embodiment of the present invention.
7 is a graph showing that an error occurs in an a-phase current sensor among three-phase current sensors in the inverter current sensor fault recognition device according to an embodiment of the present invention.
8 is a diagram illustrating a process of determining α and β currents in an inverter current sensor fault recognition device according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 shows a basic method for recognizing a fault of a current sensor in an electric vehicle. Figure 1 (a) shows the configuration of hardware, and Figure 1 (b) shows an example of checking normal/abnormal areas. In this form, a sensor may be attached to a front end of the current converter to sense the current input to the current converter. In order to check the effectiveness of the sensor, the sensor is operated by dividing it into normal/abnormal areas. If operation continues in the abnormal area, it is recognized as sensor disconnection/short circuit. However, in this case, although the sensor value is in the normal range, it cannot operate when a sensor fault occurs.

2 is a block diagram of an inverter current sensor fault recognition device according to an embodiment of the present invention.

Referring to FIG. 2 , the inverter current sensor fault recognition device 200 according to the present embodiment includes a measurement unit 210, a conversion unit 220, a calculation unit 230, a detection unit 240, and a reflux unit 250. can include

2 shows a current sensing process of the electric vehicle driving inverter according to the present embodiment. In this embodiment, current for controlling the motor of the electric vehicle may be transmitted to the electric motor 204 through the inverter 201, the gate driver 202, and the power module 203. At this time, the current transmitted from the power module 203 to the electric motor 204 may be a three-phase current.

The measuring unit 210 may measure the three-phase currents (ia, ib, ic) transmitted from the power module 203 to the electric motor 204 and check their effectiveness. As shown in FIG. 1, the method of checking the validity of the current may check whether the measured sensing value is in a normal range. In this embodiment, it is possible to check whether the sensed values of each of the three-phase currents are in a normal range, and also whether the sum of each of the three-phase currents is in a normal range. If the sum (i _sum ) of the current sensing values measured in all phases is formed to a value close to 0, it can be determined that the three-phase current sensor is a valid value. After checking the effective range of the value measured in each phase and determining the valid range of the current sensor value, the validity check result (η) is made. The validity check result for the sensed value can be represented in the table below.

ia sensor value ib sensor value ic sensor value ia + ib + ic = 0 fault(η) normal region normal region normal region normal region 0 normal region normal region normal region abnormal area One normal region normal region abnormal area abnormal area 2 normal region abnormal area normal region abnormal area 3 abnormal area normal region normal region abnormal area 4

In the above table, when η is 0, the sum of all sensor values and currents is normal, and when η is 2 to 4, the sensor values in the abnormal area are confirmed, so the location of the faulty current sensor can be accurately identified. However, when η is 1, the current sensor value for each phase appears normal, so the location of the faulty current sensor cannot be accurately identified.

In the inverter current sensor fault recognition device 200 according to the present embodiment, when the fault value η in the measuring unit 210 is 1, it can be used to find a faulty current sensor among three-phase current sensors.

The conversion unit 220 may convert currents between phases among the three-phase currents into α-β axis currents in the stationary coordinate system, respectively.

First, when all three-phase currents are valid, the currents can be converted into α-β axis currents as follows.

If there are only two-phase valid current values, the currents of phases a, b, and c can be converted into α-β axis currents as follows.

If only phase a and phase b currents are valid,

If only phase b and phase c currents are valid,

When only phase a and phase c currents are valid,

can be converted to

In (a) and (b) of FIG. 3 , a sensed value (a) of the current measured when each of the three-phase currents is sensed and a graph (b) obtained by converting it into an α-β axis current are shown.

Referring to FIG. 3 , the present embodiment shows a case where an error occurs in phase b current. In other words, an error occurred in the measured value of the b-phase current, and based on this, when converting to α-β-axis current, a circular trajectory was displayed when the a-phase and c-phase current values were used instead of the b-phase current. However, since there is an error in the b-phase current value, the α-β axis current conversion graph for the a-b phase current value and the b-c phase current value using the b-phase current is drawn in an elliptical trajectory.

The calculation unit 230 may calculate the difference between the maximum value and the minimum value of the magnitude of each of the converted current vectors.

4 shows a method of calculating the difference between the maximum value and the minimum value of magnitude for each current vector.

Referring to FIG. 4 , when all current sensor values are normal (η=0), i _α and i _β can be obtained by Equation 1 above. In this embodiment, the conversion unit 220 calculates the difference between the maximum value and the minimum value of each current vector as η = 1, which can be used to find out which current sensor has an error. That is, α-β-axis current converted i _α1 and i _β1 are obtained from the currents measured by the current sensors of phases a and b of the three-phase current sensor, and the currents measured by the current sensors of phase b and c of the three-phase current sensor α-β-axis current converted i _α2 and i _β2 are obtained from , and α-β-axis current converted i _α3 and i _β3 can be obtained from the currents measured by the current sensors of phase a and c of the three-phase current sensor. The calculation unit 230 may obtain i _mag1 , which is the size of i _α1 and i _β1 , and obtain a difference Δi _mag1 between the maximum and minimum values. In addition, i _mag2 , which is the magnitude of i _α2 and i _β2 , can be obtained, and Δi _mag2 , the difference between the maximum and minimum values, can be obtained. In addition, i _mag3 , which is the magnitude of i _α3 and i _β3 , can be obtained, and Δi _mag3 , the difference between the maximum and minimum values, can be obtained.

The detection unit 240 calculates Δi _mag1 , Δi _mag2 , and A faulty sensor can be detected by comparing Δi _mag3 .

5 illustrates a process performed in a detection unit of an inverter current sensor fault recognition device according to an embodiment of the present invention.

In this embodiment, Δi _mag1 and Δi _mag2 are first compared (541), and if Δi _mag1 is smaller than Δi _mag2 , Δi _mag1 is compared with Δi _mag3 (542). At this time, if Δi _mag1 is smaller than Δi _mag3 , the c-phase current sensor can be detected as faulty (ξ=1) (543), and if Δi _mag1 is greater than Δi _mag3 , the b-phase current sensor is detected as faulty (ξ=3) You can (545).

Δi _mag1 and Δi _mag2 are compared (541), and if Δi _mag1 is greater than Δi _mag2 , Δi _mag2 may be compared with Δi _mag3 (544). At this time, if Δi _mag3 is greater than Δi _mag2 , it can be detected that the a-phase current sensor is out of order (ξ=2) (546), and if Δi _mag2 is greater than Δi _mag3 , it is detected that the b-phase current sensor is out of order (ξ=3) You can (543).

FIG. 8 is a diagram illustrating a process of determining α and β currents using the η and ξ values calculated through the processes described in FIGS. 2 and 5 above.

The reflux unit 250 may feed back the current error to the inverter in consideration of the fault sensor detected by the detection unit 240 .

As described above, in the present embodiment, by detecting a faulty current sensor among the three-phase current sensors and controlling the inverter through the remaining two-phase current sensors without faults, the electric vehicle can be switched to emergency operation mode while maintaining operation. .

6 is a graph showing that an error occurs in a b-phase current sensor among three-phase current sensors in the inverter current sensor fault recognition device according to an embodiment of the present invention. 6(a) shows a graph of a three-phase current measured by a measuring unit in an inverter current sensor fault recognition device according to the present embodiment. As can be seen in the graph, it can be seen that an error occurred in the b-phase current sensor. In particular, it can be seen that the b-phase current sensor fault value is within the normal range and only an error occurs in the magnitude. 6 (b) converts the α-β axis current (conversion unit) to the current sensor measurement value of each phase, and Δi _mag1 , Δi mag2 , and Δi _mag2 calculated by the calculation unit It is a graph showing the value of Δi _mag3 . In the graph, Δi _mag1 and Δi _mag2 increase in size, but Δi _mag3 You can see that the size does not change. Since Δi _mag3 is obtained by obtaining i _mag3 , which is the size of i _α3 and i _β3 , and obtaining the difference between the maximum and minimum values, it can be seen that there is no error in the a-phase current and c-phase current values converted into i _α3 and i _β3 . 6(c) is a graph showing η values and ζ values in this embodiment. η = 1 in this embodiment. According to this result, Δi _mag1 , Δi _mag2 , and You can see that the Δi _mag3 value has been calculated. Δi _{mag1 and} Δi _mag2 increase, but It can be confirmed that Δi _mag3 is 0. With the proposed algorithm, ζ=3 is calculated. A-phase current and c-phase current mean that there is no abnormality.

7 is a graph showing that an error occurs in an a-phase current sensor among three-phase current sensors in the inverter current sensor fault recognition device according to an embodiment of the present invention. 7(a) shows a graph of three-phase current measured by a measuring unit in the inverter current sensor fault recognition device according to the present embodiment. Unlike FIG. 6, the current sensor value of phase a is in the normal range, but it is the result of a fault and therefore η = 1. 7 (b) converts the α-β axis current (conversion unit) to the current sensor measurement values of each phase, and Δi _mag1 , Δi mag2 , and Δi _mag2 calculated by the calculation unit It is a graph showing the value of Δi _mag3 . In the graph, Δi _mag1 and Δi _mag3 increase in size, but Δi _mag2 You can see that the size does not change. Since Δi _mag2 is obtained by obtaining i _mag2 , which is the size of i _α2 and i _β2 , and obtaining the difference between the maximum and minimum values, it can be seen that there is no error in the b-phase current and c-phase current values converted to i _α2 and i _β2 . 7(c) is a graph showing η values and ζ values in this embodiment. η = 1 in this embodiment. According to this result, Δi _mag1 , Δi _mag2 , and You can see that the Δi _mag3 value has been calculated. Δi _{mag1 and} Δi _mag3 increase, but It can be confirmed that Δi _mag0 is 0. With the proposed algorithm, ζ=2 is calculated. Phase b current and phase c current mean that there is no abnormality.

Although the above has been described with reference to the preferred embodiments and examples of the present invention, those skilled in the art will variously modify the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. And it will be understood that it can be changed.

210: measurement unit 220: conversion unit
230: calculation unit 240: detection unit
250: reflux part

Claims (4)

a measurement unit 210 for measuring and validating three-phase currents (ia, ib, ic);
a conversion unit 220 for converting currents between phases among the three-phase currents into α-β axis currents in a stationary coordinate system;
a calculation unit 230 that calculates a difference between a maximum value and a minimum value of magnitude for each of the converted current vectors;
a detection unit 240 for detecting a faulty sensor by comparing a difference between the calculated maximum value and minimum value; and
A reflux unit 250 that feeds back a current error in consideration of the detected failure sensor
Inverter current sensor fault recognition device comprising a.
According to claim 1,
In the measuring unit,
Inverter current sensor fault recognition device, characterized in that for reviewing whether the sensor value of each of the three-phase currents and the sum of the three-phase currents respectively correspond to the normal range.
According to claim 1,
The detecting unit,
The inverter current sensor fault recognition device, characterized in that for finding a difference between the calculated maximum value and minimum value of each of the converted current vectors is the minimum.
Measuring three-phase currents (ia, ib, ic) and checking validity;
a conversion step of converting currents between phases among the three-phase currents into α-β axis currents in a stationary coordinate system;
a calculation step of calculating a difference between a maximum value and a minimum value of magnitude for each of the converted current vectors;
a detection step of detecting a faulty sensor by comparing a difference between the calculated maximum value and minimum value; and
A reflux step of feeding back a current error in consideration of the detected failure sensor
Inverter current sensor fault recognition method comprising a.

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