JPH08178990A - Lightning arrester diagnosing apparatus - Google Patents

Abstract

PURPOSE: To judge the replacement of a discharger based on the lifetime (number of discharges) by diagnosing the lifetime of the discharger from the detected discharge current value and the counted number of discharging operations. CONSTITUTION: Discharge tubes 3a, 3b being discharger are connected to an equipment controller 31 to discharge a surge transient voltage invaded to the controller 31 via a control system or a communication equipment 30 to the ground 32. The phototransistors 6a, 6b of discharge detectors installed adjacently to the tubes 3a, 3b detect discharge current values from the light emissions of the tubes 3a, 3b, and output signals responsive to the light intensities. Operational amplifiers 7a, 7b amplify the output signals of the phototransistors 6a, 6b. The number of digits is increased by one every time when a shift register 8 receives the signals of the amplifiers 7a, 7b to count the number of the operations of the tubes 3a, 3b, and recorded by EEROM 10. A microprocessor 9 diagnoses the lifetimes of the tubes 3a, 3b from the discharge current values input from the ROM 10 and the register 8 and the number of the discharging operations.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lightning arrester diagnostic device built in a measuring device, a control device or the like used in various plants including general industries.

[0002]

2. Description of the Related Art FIG. 6 shows a circuit diagram of a lightning arrester for a two-wire measuring instrument which has been conventionally used.

Reference numeral 1 is a main circuit of a measuring instrument, 2 is a lightning arrester circuit, 3a and 3b are lightning arresters such as a discharge tube and a varistor which constitute a lightning arrester circuit, and 5 is for suppressing the potential difference of an input power source to the measuring instrument to be a certain voltage or less. Zener diode, 4
a and 4b are protection resistors.

In the above device, the arrester circuit 2 is designed so that the discharge tube discharges at a voltage higher than the power supply voltage used by the main circuit 1 of the measuring instrument and lower than the withstand voltage, and surge voltage due to inductive lightning or the like is generated by the power source. Has a function to escape to the ground when it enters from the line. In addition, the protection resistors 4a, 4
b prevents the overcurrent from flowing into the main circuit 1 of the measuring instrument. Furthermore, with the Zener diode 5,
The potential difference of the input power supply to the measuring equipment is kept above the power supply voltage used and below the withstand voltage.

[0005]

In the prior art shown above, the arrester has a life depending on the number of discharges.
Since there is no means to judge the life and the replacement time is unclear, it is usually recommended to replace it regularly regardless of the number of discharges.

An object of the present invention is to provide a lightning arrester diagnostic device capable of judging replacement of a lightning arrester based on the life (the number of times of discharge).

[0007]

A lightning arrester diagnostic device of the present invention is installed in combination with a discharger which is connected to an equipment control circuit and discharges a surge transient voltage entering the equipment control circuit to the ground. A discharge detector that detects the value of the discharge current flowing through the discharger, a recording device that records the number of discharge operations of the discharger counted by the discharge detector, and a lifetime diagnosis of the discharger based on the discharge current value and the number of discharge operations A life calculator is provided. The lightning arrester diagnostic device according to a second aspect of the present invention is characterized in that a booster circuit for applying a boosted test voltage to the device control circuit to diagnose the life is connected.

[0008]

In the arrester diagnostic device of the present invention, a surge detector is installed in combination with the discharger by connecting the discharger to the device control circuit to discharge the surge transient voltage entering the device control circuit to the ground. Detects the discharge current value flowing in the discharger,
The number of discharge operations of the discharge device counted by the discharge detector is recorded, and the life of the discharge device is diagnosed based on the discharge current value and the number of discharge operations. The lightning arrester diagnostic device according to claim 2 is characterized in that the boosted test voltage is applied to the device control circuit to diagnose the life.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of the housing grounding device of the present invention will be described. In FIG. 1, the discharge tubes 3a and 3b are device control circuits 3 to which a control system or a communication device 30 is connected.
The surge transient voltage that is connected to the control system or communication device 30 and enters the device control circuit 31
It is a discharger that discharges to 2. Phototransistor 6a,
Reference numeral 6b is a discharge detector which is installed in the equipment control circuit 31 adjacent to the discharge tubes 3a and 3b, detects light emitted by the discharge tubes 3a and 3b, and outputs a signal according to the intensity of the light emission. The operational amplifiers 6a, 6b are phototransistors 6a,
A differential operational amplifier connected to 6b and amplifying the output signals of the phototransistors 6a and 6b. The shift register 8 is connected to the operational amplifiers 6a and 6b,
This is a counter circuit that counts the number of operations by incrementing the number of digits by one each time the signals from a and 6b are received. E ² R
The OM 10 is a recording device for recording the discharge operation circuits of the discharge tubes 3a and 3b counted by the phototransistors 6a and 6b. Microprocessor 9 is connected to the E ² ROM 10 and shift register 8 is the discharge tubes 3a, lifetime calculator that performs lifetime diagnosis 3b and a discharge current value and the discharging operation number inputted from the E ² ROM 10 and shift register 8 . The protection resistors 4a and 4b are connected in series to the device control circuit 31 to correct the circuit impedance. The Zener diode 5 is connected between the lines of the device control circuit 31 and protects the control system or the communication device 30 from the voltage rise of the circuit.

That is, 1 is a main circuit of a measuring device such as a pressure transmitter having a microprocessor 9 incorporated therein, 2
Is a lightning arrester circuit attached to the input part of the measuring device, which is composed of discharge tubes 3a and 3b, protective resistors 4a and 4b, and Zener diode 5, and the discharge tubes 3a and 3b have discharge tubes 3a and 3b.
Phototransistors 6a and 6b are arranged to detect light generated when b is discharged. 7a and 7b are operational amplifiers for amplifying the detection signal, and are the main circuit 1 of the measuring instrument.
Includes a shift register 8 for counting the detection signal of the amplified discharge light, a microprocessor 9, and an E ² PROM 10.
Is provided.

The above measuring device is, for example, a two-wire type,
It is driven by the 4VDC power supply 35 and outputs the output signal of 4 to 20 mA DC to the host control system side.

In the system of the measuring equipment shown in FIG. 1, lightning strike may cause surge due to induced lightning to enter the power supply line. In this case, the operation of the arrester circuit 2 protects the main circuit 1 of the measuring device. The discharge tubes 3a and 3b in the lightning arrester circuit are discharged when a voltage of, for example, 230 V or more is applied, and thus are discharged by a surge, and the light generated at this time is detected as an electric signal by the phototransistors 6a and 6b. This signal is the operational amplifier 7a, 7
After being amplified by b, the shift register 8 counts and stores the number of discharges. The microprocessor reads the periodic count number and stores the total number of discharges in the E ² PROM 10. The number of discharges can be transmitted to the host control system by using the communication function of the measuring device and can be called from the communication device such as a handheld terminal.

According to the present embodiment, the lightning arrester has been replaced irrespective of whether the life of the lightning arrester is old or not, regardless of whether or not it has a life (the number of discharges). However, since the number of discharges can be recalled at any time by the above configuration, no replacement is required. It becomes economical because there is no waste of exchanging even large items.

FIG. 2 shows a modification of the embodiment shown in FIG.

In this embodiment, the discharge tube 3 of the embodiment shown in FIG. 1 is used.
As a means for detecting the discharge of a and 3b, the magnetic sensor 12
a and 12b are used. As a configuration, the coils 11a, 1 are provided in the path between the discharge tubes 3a, 3b and the ground 32.
1b and magnetic sensors 12a and 12b are provided.

In operation, the discharge tube 3 is caused by a lightning surge.
When a and 3b are discharged, a current flows through the coils 11a and 11b to generate a magnetic field, but the magnetic sensors 12a and 12b are used.
This magnetic field is detected and converted into an electric signal.
The processing of this detection signal is exactly the same as that according to FIG.

The discharge tubes 3a and 3b are shown in FIG.
Unlike the case, a varistor may be used.

Further, in FIG. 3, the lightning arrester 3 is connected to the power line.
The current transfer 13a, 13b for detecting the current is provided on the path leading to the ground 32 via a, 3b (which may be a discharge tube or a varistor). The current transferred to the ground 32 by the lightning surge is transferred to the current transfer 13
a, 13b, and by this detection signal, the arrester 3a,
The number of discharges of 3b is counted. The processing of the detection signal is the same as in the case of FIG.

FIG. 4 shows another embodiment of the present invention.

1 to 3 indirectly detect the current flowing through the lightning arrester, the present invention directly detects the high voltage generated at the input portion of the main circuit 1 of the measuring instrument by the high voltage detection circuit 14. Is to be detected by.

The configuration is such that the high voltage detection circuit 14 is provided between the lightning arrester circuit 2 and the main circuit 1 of the measuring instrument.

The operation of the present invention will be described below. When a surge voltage is applied to the power supply line, the lightning arresters 3a and 3b are discharged and fixed at the break voltage V _A. At the point A, the Zener diode 5 fixes the break voltage V _Z of the Zener diode. The condition at this time is V _Z <
<V _A. Note that V _Z is set to a value larger than the rated maximum voltage of the main circuit 1 of the measuring device.

Therefore, the surge arrester 3 is applied with the surge voltage.
When a and 3b are discharged, the point A becomes the break voltage V _Z , and the voltage dividing resistors 15a and 15b in the high voltage detection circuit 14 are discharged.
The voltage is divided by the resistance values R ₁ and R ₂ , respectively, and when the value is equal to or higher than the signal detection level of the inverter 16, the shift register 8 counts and stores the number of discharges.
The storage of data in the E ² PROM 10 by the microprocessor 9 is the same as in the previous embodiment.

The voltage dividing conditions for the resistance values R ₁ and R ₂ are set so that (V _Z · R ₂ ) / (R ₁ + R ₂ )> V _IC1 . V _IC1 is the signal detection level of the inverter. Further, if the allowable leak current is IR and the maximum rated voltage of the measuring device is V _E , the resistance is selected so that (R ₁ + R ₂ ) >> (V _E / IR).

FIG. 5 shows an embodiment of claim 2. In contrast to the previous embodiment in which the booster circuit 17 and the switch 18 are provided to check the life by detecting the number of discharges, here,
This is a method of actually generating a high voltage and examining the discharge performance of the lightning arrester. Further, as compared with the embodiment of FIG.
a, 19b and Zener diode 20 are added.

Next, the operation of this apparatus will be described. now,
It is assumed that the booster circuit 17 and the switch 18 are operated by a command from the microprocessor 9 when a diagnostic command for the lightning arrester is issued by communication means such as a handheld terminal, and a surge voltage of, for example, 300 V is generated. At this time, the arresters 3a, 3
b break voltage is 230V, the circuit voltage when the surge arrester 3a, 3b to function properly fixed to 230V, further main circuit 1 is fixed to V _Z for example 85V by the zener diode 21 instrumentation is protected. (in this case,
Since the break voltage of the Zener diode 20 is set to 250V, it does not operate. ) The lightning arrester deteriorates, the break voltage increases, and 250V
When the voltage exceeds the limit, the Zener diode 20 operates due to the surge voltage of 300 V generated in the booster circuit, and the circuit voltage becomes 25
It is fixed at 0V. At this time, the voltage dividing resistors 15a and 15b
250V is divided by (R ₁ , R ₂ ) and the inverter 1
6 operates and is stored in the shift register 8. Therefore, the life of the lightning arresters 3a and 3b can be determined by checking the count state of the shift register 8, that is, the presence or absence of the operation of the Zener diode 20, with the microprocessor 9. This result is transmitted to a communication device such as a handheld terminal by communication, and the result of determination whether replacement is necessary or not is displayed.

In this case, the circuit voltage is, for example, 300V.
Even if it becomes higher, the circuit voltage is fixed to 85V, which is lower than the rated voltage of the measuring device, by the functions of the protection resistors 19a and 19b and the Zener diode 21, and the main circuit of the measuring device is not damaged.

The voltage _dividing conditions for the resistance values R1 and R2 are set so that (V _Z1 · R ₂ ) / (R ₁ + R ₂ )> V _IC1 . V _IC1 is the signal detection level of the inverter. Further, if the allowable leak current is IR and the maximum rated voltage of the measuring device is V _E , the resistance is selected so that (R ₁ + R ₂ ) >> (V _E / IR).

[0029]

According to the present invention, it is possible to improve the accuracy of the life arrestor life diagnosis.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of a lightning arrester diagnostic device.

FIG. 2 is a partial configuration diagram showing another embodiment.

FIG. 3 is a partial configuration diagram showing another embodiment.

FIG. 4 is a configuration diagram showing another embodiment.

FIG. 5 is a configuration diagram showing an embodiment of claim 2;

FIG. 6 is a configuration diagram showing a conventional example.

[Explanation of symbols]

 3a, 3b Discharge tube 4a, 4b Protection resistor 5 Zener diode 6a, 6b Phototransistor 7a, 7b Operational amplifier 8 Shift register 9 Microprocessor

Claims (2)

[Claims] 1. A discharger connected to a device control circuit for discharging a surge transient voltage entering the device control circuit to the ground, and a discharge current value flowing in the discharger installed in combination with the discharger Discharge detector, a recording device for recording the number of discharge operations of the discharger counted by the discharge detector, and a life calculator for performing life diagnosis of the discharger from the discharge current value and the number of discharge operations. ,
An arrester diagnostic device comprising: 2. The surge arrester diagnostic device according to claim 1, further comprising a booster circuit connected to the device control circuit for diagnosing a life by applying a boosted test voltage.