JPH05120945A - Contact wear monitoring device - Google Patents

Abstract

PURPOSE:To provide an excellent contact wear monitoring device capable of highly precisely monitoring the degree of wear of contacts of the breaker without impairing the reliability of a control circuit for the breaker. CONSTITUTION:During operation of a breaker 31, a current information 39 from a current transformer 33 of a main circuit 32 is subjected to sampling by sampling means (34, 36 to 38) at fixed time intervals. Of the sampled current information items 39, those obtained from the present time point up to a time point preceding, by a specified time length, to the present time point are always stored in a storage means 38. An operation signal of the breaker 31 is detected by a timing detection means 38. On the basis of the operation signal 40 detected by the timing detection means 38, a cutoff energy is calculated, by a calculation means 38, from a current information 39 stored in the means 38.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for monitoring the degree of wear of contacts of a power circuit breaker.

[0002]

2. Description of the Related Art Conventionally, several methods for monitoring contact wear have been proposed for the purpose of improving the efficiency of inspection of power circuit breakers. As such a technique, for example, as disclosed in JP-B-49-46583 and JP-A-55-32349, the main circuit current is detected and the current peak value is weighted, or There is a technique for obtaining the breaking energy by multiplying the current value by the time factor and calculating the degree of wear of the circuit breaker contact based on this data. FIG. 3 is a block diagram showing the configuration of the contact wear monitoring device disclosed in Japanese Patent Laid-Open No. 55-32349 among such techniques.

In FIG. 3, 7 is a main circuit and 9 is a main circuit 7.
A current transformer, 12 is a manipulator, 16 is a manipulator 12
It is a circuit breaker operated by. That is, in FIG. 3, with the current flowing in the main circuit 7, the operating device 12
When a break command is given to the circuit breaker 16, the circuit breaker 16 starts the opening operation to generate an arc, and after the arc is extinguished, the break is completed. This arc current is detected by the current transformer 9, and the amplifier 17
To convert to a level value that is easy to calculate.

FIG. 4 is a signal waveform diagram showing an example of the timing of the input signal during the interruption operation to the contact wear monitoring device of FIG. In FIG. 4, t1 is the contact opening time of the circuit breaker, t2 is the arc time that changes according to the magnitude of the current in the main circuit 7, and the total time t0 (total of the contact opening time t1 and the arc time t2 ( t0 = t1 + t2)
Is the cutoff time. Therefore, the contact opening time t peculiar to the circuit breaker
By inputting 1 through the console 26, this opening time t1 is obtained by the counter 21. That is, the main contact "open" excitation to the operating device 12 starts the counter 21 and sets the pulse to be generated until the set time t1.

With this setting, the data transmission start of the element separator 18 becomes t1. The element separator 18 divides the signal from the amplifier 17 in the previous stage into elements of current value (kA) and time, and at t1 time, an individual amplifier 19 in the subsequent stage.
To start sending data to. The current value signal and the time signal are respectively amplified by the individual amplifiers 19, and then the arithmetic unit 2
It is sent to 0 and converted into arc value E of current value x time.

The data (arc energy E) thus obtained by the arithmetic unit 20 is sent to the shift register 22 and further to the comparison arithmetic unit 24. in this case,
Since the gate is opened by the output pulse of the counter 21, the data (arc energy E) is input to the comparison calculator 24. The data (arc energy E) output from the comparison calculator 24 is input to the memory 23,
Recorded and entered by console 26,
The electrode contact wear amount unique to the circuit breaker is compared, and when a certain alarm value is reached, an alarm is displayed by the display 25.

[0007]

By the way, in the conventional contact wear monitoring device as described above, the operating device 12 of the circuit breaker 16 is used.
Also, since it is directly connected to the current transformer 9 for the control circuit and is configured by modifying the control circuit of the circuit breaker, in such a configuration, a malfunction occurs on the contact wear monitoring device side. In this case, a fault current may flow and the control circuit of the circuit breaker may be adversely affected.
Further, in measuring the arc time, as described above,
There is also a drawback that high accuracy cannot be obtained without considering not only the magnitude of the main circuit current but also the influence of the phase. Furthermore, since a counter is required to measure the operating time of the circuit breaker, this has the drawbacks of complicating the system and increasing cost.

The present invention has been proposed in order to solve the above-mentioned problems of the prior art, and its object is the contact wear degree of the circuit breaker without impairing the reliability of the control circuit of the circuit breaker. An object of the present invention is to provide an excellent contact wear monitoring device capable of accurately monitoring the contact.

[0009]

A contact wear monitoring apparatus according to the present invention is a contact wear monitoring apparatus which measures current consumption from a main circuit current transformer during operation of a circuit breaker to measure electrode wear of the breaker. , Sampling means for sampling the current information from the main circuit current transformer at constant time intervals, and of the current information sampled by the sampling means, the current information from the present time to a predetermined time before is always stored Storing means, timing detecting means for detecting an operation signal of the circuit breaker, and the operation signal detected by the timing detecting means as a reference,
It is characterized by having a calculating means for calculating the breaking energy from the current information stored in the storing means.

Specifically, it is possible to detect a signal of an auxiliary contact generally provided for controlling a circuit breaker as an operation signal of the circuit breaker. When sampling the current information of the main circuit current transformer, instead of directly sampling the current of the main circuit current transformer, an auxiliary current transformer is provided in the secondary circuit of the main circuit current transformer, and this auxiliary current transformer is used. It is desirable to sample the current through the instrument. Further, a microcomputer can be used as the sampling means, the storage means, the timing detection means, and the calculation means, and the processing can be performed by software.

[0011]

In the contact wear monitoring device of the present invention having the above-mentioned structure, the timing means can easily detect the operation timing of the circuit breaker, and the sampling means samples the current information of the main circuit current transformer. ,
Since the storage unit can store the current waveform at a constant time interval, it is possible to easily measure the relationship between the current value and the phase when an arc occurs. Therefore, the breaking energy can be accurately calculated by the calculating means with reference to the sampled current waveform for a certain period, and as a result, the degree of wear of the contact can be accurately monitored.

Further, for sampling the current of the main circuit current transformer and detecting the operation signal of the circuit breaker, it is not necessary to directly connect the sampling means and the timing detection means to the operation device or control circuit of the circuit breaker, and the auxiliary current It can be realized by a method such as sampling the current of the container or detecting the signal of the auxiliary contact. Therefore, since it is not necessary to modify the control circuit of the circuit breaker, even if a failure occurs on the contact wear monitoring device side, the control circuit of the circuit breaker is not adversely affected. Furthermore, since it is not necessary to modify the control circuit of the circuit breaker, it excels in compatibility with existing equipment. In particular, when a microcomputer is used, the configuration is simple and the practicability is excellent.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the contact wear monitoring device according to the present invention will be specifically described below with reference to FIGS. In this case, FIG. 1 is a block diagram showing the configuration of the contact wear monitoring apparatus, and FIG. 2 is a signal waveform diagram showing an example of the timing of the input signal during the interruption operation to the contact wear monitoring apparatus of FIG. .

In FIG. 1, 31 is a circuit breaker, 32 is a main circuit, 33 is a current transformer provided in the main circuit 32, and an auxiliary current transformer 34 is provided in a secondary circuit of the current transformer 33. It is installed. That is, since the current transformer 33 is for a control circuit, in the present embodiment, the current consumption is sampled via the auxiliary current transformer 34 without directly connecting the contact wear monitoring device to the current transformer 33. Is configured to do. The auxiliary current transformer 34 has a current-voltage converter (I / V) 3
6, the A / D converter 37, and the CPU 38 are sequentially connected. In this case, the current / voltage converter (I / V) 36, A
The / D converter 37 and the CPU 38 are configured by one board, and an 8-bit or 16-bit microcomputer is used as the CPU 38. In addition, the auxiliary contact (b contact) 35 provided in the circuit breaker 31 is connected to the CPU 3
8 is connected. In the figure, 50 is a load.

On the other hand, in FIG. 2, the waveform 39 shows the current waveform of the main circuit 32, and the waveform 40 shows the signal waveform of the auxiliary contact (b contact) 35 of the circuit breaker 31. These waveforms 3
In FIGS. 9 and 40, time a indicates the time when the arc occurs, time b indicates the time when the arc ends, and time c indicates the time when the contact of the circuit breaker b opens, that is, the time when the breaking operation ends. The time length between a and c is
It becomes a value peculiar to the device, and the time length between a and b changes depending on conditions such as the magnitude and phase of the main circuit current.

In the contact wear monitoring device shown in FIG. 1, the CPU 38 is programmed to perform the following series of operations, for example, to accurately monitor the wear of the breaker contacts. it can.

First, the signal from the auxiliary current transformer 34 is input to a current / voltage converter (I / V) 36 to convert the current waveform into a voltage waveform, and then digitized by an A / D converter 37. , To the CPU 38. The CPU 38 always
A waveform as shown in FIG. 2 is sampled at fixed time intervals (for example, 1 ms), and waveform data for 3 cycles is stored. That is, the CPU 38 always stores the data from a certain reference time point up to the time of 3 cycles in the memory, and updates the past data one by one each time the data is fetched.

During the breaking operation of the circuit breaker 31, the CPU 38 pauses the sampling of the waveform data by the b-contact signal of the auxiliary contact signal, and a certain time before the b-contact signal, that is, until the main contact is opened. The breaking energy is calculated based on the current waveform corresponding to time, and the obtained breaking energy value data is output. Subsequently, this data is transmitted to a high-order CPU (not shown),
While being stored, the degree of wear of the circuit breaker contact is calculated from the integrated value. Further, when the degree of consumption reaches a predetermined level, an alarm is output and a certain process such as displaying that it is the inspection time is performed.

In the contact wear monitoring apparatus of the present embodiment as described above, the above-mentioned Japanese Patent Publication No. 49-46583,
The following advantages can be obtained as compared with the prior arts such as Japanese Patent Laid-Open No. 55-32349. That is, in the present embodiment, since the current waveform is sampled and captured, a method of weighting and storing the current peak value,
The breaking energy can be calculated more accurately than the method in which the current value is multiplied by the time factor and stored.

Further, as shown in FIG. 3, the operating time measuring means (counter 21) of the circuit breaker, which is required in the prior art, can be omitted, so that the structure is simplified accordingly. There is also an advantage that the cost can be reduced. In particular, in this embodiment, since all the important functions of sampling, storage, timing detection, and calculation are configured to be performed by the CPU 38, the configuration is extremely simple and the cost can be further reduced.

The present invention is not limited to the above-mentioned embodiment, and various programs can be used as a concrete program of the CPU, for example. Further, it is not necessary to configure all of the sampling means, storage means, timing detection means, and calculation means by one CPU, and it is possible to use a plurality of CPUs or use other means.

[0022]

As described above, according to the present invention,
By sampling the current waveform of the main circuit current and using this current waveform as a reference to calculate the breaking energy,
It is possible to provide an excellent contact wear monitoring device capable of accurately monitoring the contact wear of the breaker without impairing the reliability of the control circuit of the breaker.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a contact wear monitoring device according to the present invention.

2 is a signal waveform diagram showing an example of the timing of an input signal at the time of a breaking operation to the contact wear monitoring device of FIG.

FIG. 3 is a block diagram showing a configuration of a conventional contact wear monitoring device.

FIG. 4 is a signal waveform diagram showing an example of the timing of an input signal at the time of a breaking operation to the contact wear monitoring device.

[Explanation of symbols]

 7 ... Main circuit 9 ... Current transformer 12 ... Operator 16 ... Breaker 17,19 ... Amplifier 18 ... Element separator 20 ... Calculator 21 ... Counter 22 ... Shift register 23 ... Memory 24 ... Comparison calculator 25 ... Display 26 ... Console 31 ... Circuit breaker 32 ... Main circuit 33 ... Current transformer 34 ... Auxiliary current transformer 35 ... Auxiliary contact (b contact) 36 ... Current-voltage converter (I / V) 37 ... A / D converter 38 ... CPU 39 ... Main circuit current waveform 40 ... Auxiliary contact signal waveform 50 ... Load a ... Arc occurrence time b ... Arc end time c ... Breaking operation end time

Claims (1)

[Claims] 1. A contact wear monitor for measuring current consumption from a main circuit current transformer during operation of a circuit breaker to measure the degree of electrode wear of the circuit breaker. A sampling means for sampling at a fixed time interval, a storage means for constantly storing the current information from the current time to a fixed time before among the current information sampled by the sampling means, and an operation signal of the circuit breaker are detected. And a contact consumption monitor for calculating the breaking energy from the current information stored in the storage unit with reference to the operation signal detected by the timing detection unit. apparatus.