JPH11160377A - Deterioration detection system of capacitor for power converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect-capacitor deterioration by grasping capacity reduction of online capacitor without influence by a DC ripple voltage that varies greatly by load current and rotary frequency of an AC motor. SOLUTION: A power converter system comprises a converter 1 that generates a variable DC power supply from a commercial power supply 10, an inverter 2 that generates a variable frequency power from a variable DC power supply, and supplies the power to a motor 11, and a capacitor 3 connected to the variable DC power supply. Further a filter method 4 that inputs a carrier frequency component 22 of an inverter 2 and voltage between both capacitor- terminals and detects ripple voltage synchronized with a carrier frequency component 22, and a setting method 6 to set a value corresponding to a motor load current are installed. When peak-hold value 25 of the ripple voltage becomes more than value that set value 26 by a specified value, it is judged that capacitor capacity is deteriorated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for detecting deterioration of a capacitor used in a power converter that outputs a variable frequency (including direct current) from a commercial power supply, and more particularly, to a technique for detecting a decrease in capacity of a capacitor (deterioration over time). About.

[0002]

2. Description of the Related Art Conventionally, various detection methods are known as techniques for detecting a decrease in capacity (deterioration over time) of a capacitor used in a power converter. The first is disclosed in JP-A-8-1813.
No. 43, and according to this publication, the detection methods include (1) detecting a decrease in power conversion efficiency, (2) detecting an input voltage as a current, an output voltage and a current for that purpose,
(3) A method of calculating the power conversion efficiency and detecting a decrease from an initial value, and (4) judging deterioration of the capacitor over time based on the detection. But,
In this method, the measurement method is complicated and the cost increases, and furthermore, the decrease in efficiency is very small in a general power converter.
There is a great possibility that other factors may be erroneously determined to be aging of the capacitor. The second method is described in Japanese Patent Application Laid-Open No. 4-19073. The detection method according to this publication measures the charging time of a capacitor, and if the capacitor deteriorates, the capacity of the capacitor decreases. It is a method of catching and detecting aging deterioration. But,
In this method, the converter must be stopped and restarted to charge the capacitor. Therefore, it cannot be used online (during operation of the converter). In fact, power converters are used in uninterruptible power supplies and continuous production facilities, so shutting down often results in economic losses. No. 3 is described in Japanese Patent Application Laid-Open No. 4-192521.
In contrast to Japanese Patent Application Laid-Open No. 19073, which uses charging time, aging is detected using discharging time. Since this method can be used only online, the disadvantage is the same as the method using the charging time. No. 4 is disclosed in
The detection method disclosed in Japanese Patent Application Laid-Open No. 248086 is a method in which a ripple of a DC power supply is extracted and compared with a reference signal to detect deterioration of a capacitor. However, inverters and converters that generate a variable frequency power supply have many ripples, and the load current constantly changes between plus and minus, so that the ripple voltage value also changes greatly. Therefore, this method is inappropriate as a method to detect the deterioration of the capacitor,
Obviously it cannot be used.

[0003]

It is generally known that a capacitor used in a power converter or the like deteriorates with time (decrease in capacitor capacity) (particularly, when the temperature of the capacitor is 8 to 10). Each time the temperature rises, the life is reduced by half.) However, measuring the life of a capacitor in an actual power converter or the like and replacing it with a new capacitor takes time and labor and involves great difficulty. (1) Aging usually occurs after 5 to 10 years or more. During this time, it is necessary to measure and monitor the capacity of the condenser economically. (2) To measure the capacitance of the capacitor, the power converter must be stopped and only the capacitor must be disconnected from the main circuit.

SUMMARY OF THE INVENTION An object of the present invention is to eliminate the drawbacks of the conventional direct measurement method, to continuously capture the decrease in the capacity of an on-line capacitor, and to directly change the DC current which varies greatly depending on the load current and rotation frequency of an AC motor. An object of the present invention is to provide a method for detecting deterioration of a capacitor for a power converter, which is suitable for detecting deterioration of a capacitor without being affected by side ripple voltage.

[0005]

SUMMARY OF THE INVENTION The object of the present invention is to detect a ripple voltage at both ends of a capacitor synchronized with a carrier frequency component of an inverter, and when the ripple voltage exceeds a value corresponding to a motor load current by a predetermined value or more. The problem is solved by determining that the capacity has deteriorated.

[0006]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a method for detecting deterioration of a capacitor for a power converter according to an embodiment of the present invention. In FIG. 1, an AC variable motor system includes a thyristor converter, a transistor converter, and a gate turn-off thyristor (G
It comprises a converter (CONV) 1 such as a TO) converter, an IGBT (insulated gate bipolar transistor) converter, an inverter (INV) 2 having a switch element (transistor, GTO, IGBT, etc.), and an electrolytic capacitor (C) 3. Here, reference numeral 10 denotes a commercial AC power supply (AC), and 11 denotes an AC motor (ACM). Capacitor deterioration detection system consists of filter (FLT) 4, comparator (CMP)
5, a setting unit (VR) 6, and an AND gate 7. FIG.
, A variable DC power supply (V _DC ) 23 is generated from the commercial AC power supply 10 using the converter 1, and a DC current I _DC flows from the converter 1 to the capacitor 3 to charge the capacitor 3. The voltage across capacitor 3 is
A U-phase alternating current including a ripple current synchronized with the carrier frequency fc is converted into a three-phase alternating current (U, V, and W phases) by the on and off frequencies of the switch element of the inverter 2 (this is referred to as a carrier frequency). Current I _U 24 (V
The same applies to I _V and I _W of the phase and the W phase. Only I _U will be described below. ) Flows into the AC motor 11.

This state will be described with reference to FIGS.
FIG. 2 shows a part of the inverter 2 of the present embodiment, and FIG.
Shows a time chart of the inverter unit. In the case of FIG. 2, the inverter 2 is a transistor Q as a switch element.
_UP ~Q consists of _WN, frequency of on and off the transistor is a carrier frequency fc, the carrier frequency fc
Is a predetermined value. The on / off ratio of the transistor varies from 0 to 100%. The first line in FIG. 3 shows the line voltage _VUV and the period T _C = 1 / fc when the transistor Q _UP is turned on and off and the carrier frequency is fc. The U-phase alternating current I _{U including} the ripple current δI _DC shown in the second stage of FIG. 3 is supplied to the AC motor 11 by the line voltage V _UV and the cycle T _C. At this time, the voltage _VDC across the capacitor 3 includes the ripple voltage δ shown in the third stage of FIG.
_VDC occurs. This principle can be expressed by equation (1). That is, δV _DC ∞ (1 / C) δI _DC × T _ON = (1 / C) δI _U × T _ON (1) where C is the capacitance (F) of the capacitor, and δI _DC is the change of the DC side current ( A) δI _U is a change in the U-phase current (A) T _ON is a time (second) during which the transistor Q _UP is on. Therefore, it can be seen that when the value of the capacitance C of the capacitor 3 deteriorates with age and the capacitance decreases, δV _DC dependent on the carrier frequency fc increases. The AC motor 11
Even if the U-phase alternating current (load current) I _U of
_It can be seen that _DC increases and δV _DC also changes with T _ON .

Therefore, in this embodiment, (1) the ripple voltage δV _DC is greatly affected by the carrier frequency component fc and the ON time T _ON of the switching element of the converter, and (2) the ripple voltage δV _DC is , the load when the current I _U is large, a relatively large, (3) the frequency components of the ripple voltage .DELTA.V _DC proportional to the rotational speed of the motor also changes greatly, but the carrier frequency component fc is sufficiently rpm frequency Focusing on the fact that a larger value is often used as compared with that of FIG.
, A variable DC voltage V _DC 23 and a carrier frequency fc 22 are input to the converter, and only the ripple voltage δ _VDC dependent on the ON time T _ON of the switching element of the converter is extracted in synchronization with the carrier frequency fc to obtain a ripple peak voltage signal 25. .

FIG. 4 shows a detailed filter circuit of the filter 4. This filter circuit includes an analog switch 31, a differentiating circuit 32, and a peak holder circuit 33. As shown in FIG. 4, the variable DC voltage V
_{When the DC} 23 is input and the analog switch 31 is closed by the ON signal of the switch element of the converter at the carrier frequency fc22, the differentiating circuit 32 causes the variable DC voltage V _DC 23
Differentiating the ripple voltage δV _DC. The differential output value is peak-held by a peak-hold circuit 33.
Thus, synchronized with the carrier frequency fc, extracting only ripple voltage .DELTA.V _DC which depends on the on-time T _ON of the switching element of the transducer, it is possible to obtain a ripple peak voltage signal 25.

FIG. 5 shows a time chart of the filter circuit shown in FIG. (A) is an on / off signal of the switch element of the converter at the carrier frequency fc22, (b)
Is the ripple voltage δV _DC of the variable DC voltage V _DC 23, (c)
Is a differential output, and (d) is a peak hold output. The solid line in the figure shows the value when the capacity of the capacitor 3 is the initial value, and the broken line shows the value when the capacity is reduced due to aging. As shown in the figure, under the same condition that the carrier frequency fc22 and the ON time of the switch element of the converter are the same, the ripple voltage δ
_VDC is compared to when the capacity of the capacitor 3 is the initial value,
When the capacity decreases, the value increases, and the peak hold value increases.

Next, the ripple peak voltage signal 25 obtained by the filter 4 is input to the comparator 5, while the motor 1
Detected by one of the load current I _U current transformer CT, as previously described, the ripple voltage .DELTA.V _DC, when the load current I _U is large, it becomes relatively large, the load current I _U of the electric motor 11 An appropriate set value 26 is set in the setter 6, and the set value 26 and the ripple peak voltage signal 25 are compared.
As a result of the comparison, if the ripple peak voltage signal 25 of the carrier frequency component fc is large, the capacitor deterioration signal 21 is output as an abnormal signal. Here, the capacitor deterioration signal 21 is the operation instruction 12 of the AC motor 11.
Is output through the AND gate 7 in order to prevent a malfunction at the time of starting / stopping the entire system.

[0012]

As described above, according to the present invention,
It is possible to detect the deterioration of the capacitor of the power converter online (during continuous operation). In addition, since the ripple voltage that depends on the carrier frequency is detected, deterioration of the capacitor of the power converter can be detected without being affected by the ripple voltage on the DC side that changes greatly depending on the load current and the rotation frequency of the AC motor. Can be. Also,
Since there is no need to stop the power converter and measure the deterioration of the capacitor, the cost for maintaining the capacitor can be significantly reduced as compared with the conventional method. In addition, since the power converter is not stopped, there is no need to stop operation,
Productivity can be significantly improved.

[Brief description of the drawings]

FIG. 1 is a method for detecting deterioration of a capacitor for a power converter according to an embodiment of the present invention.

FIG. 2 is a detailed view of the power converter of the present invention.

FIG. 3 is a time chart of the power converter unit of the present invention.

FIG. 4 shows a detailed filter circuit of the present invention.

FIG. 5 is a time chart of the filter circuit of the present invention.

[Explanation of symbols]

1 ... Converter (CONV), 2 ... Inverter (IN)
V), 3 ... electrolytic capacitor (C), 4 ... filter (F
LT), 5 ... Comparator (CMP), 6 ... Setting device (VR)
6, 10: Commercial AC power supply (AC), 11: AC motor (ACM), 31: Analog switch, 32: Differentiating circuit, 33: Peak hold circuit

Claims (3)

[Claims] 1. A converter for generating a variable DC power supply from a commercial power supply, an inverter for generating a variable frequency power from the variable DC power supply and supplying the power to an electric motor, and a capacitor connected to the variable DC power supply. In a power conversion system, a ripple voltage across a capacitor synchronized with a carrier frequency component of an inverter is detected, and when the ripple voltage exceeds a value corresponding to a motor load current by a predetermined value or more, it is determined that the capacitance of the capacitor has deteriorated. A method for detecting deterioration of a capacitor for a power converter. 2. A converter for generating a variable DC power supply from a commercial power supply, an inverter for generating a variable frequency power from the variable DC power supply and supplying the power to an electric motor, and a capacitor connected to the variable DC power supply. In the power conversion system, a filter means for inputting a carrier frequency component of an inverter and a voltage between both ends of a capacitor and detecting a ripple voltage synchronized with the carrier frequency component, and a means for setting a set value corresponding to a motor load current are provided. A method for detecting deterioration of a capacitor for a power converter, comprising determining that the capacity of the capacitor has deteriorated when the voltage has exceeded a predetermined value or more. 3. The method of detecting deterioration of a capacitor for a power converter according to claim 2, wherein said filter means differentiates said ripple voltage by a differentiating circuit and peak-holds the differential output value by a peak hold circuit. .