JPH05115111A - Gas leakage monitor for gas insulated electric apparatus - Google Patents

Abstract

PURPOSE:To get a gas leakage monitor for a gas insulating electric apparatus where leakage of insulating gas inside a container can be found out at an early stage and a temporal margin enough for taking countermeasure of gas leakage can be gotten. CONSTITUTION:An arithmetic unit 15 receives pressure information from a pressure sensor 9, temperature information from a temperature detection means and time information from a time measuring means 14, and operates a gas pressure expressed in terms of a reference temperature, based on these pressure information, temperature information, reference gas temperature information, and reference gas pressure information, and then operates a gas pressure drop rate based on this gas pressure expressed in terms of the reference temperature and the time information, thus operating a residual time to an allowable lower limit gas pressure based on the gas pressure drop rate and the gas pressure expressed in terms of the reference temperature. The alarm signal output means in the arithmetic unit 15 outputs an alarm signal when the gas pressure drop rate gets over a specified gas pressure drop rate, and outputs an alarm signal when the residual time falls below a specified residual time. An indication means 18 indicates the pressure drop rate and the residual time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention accommodates a main body of electric equipment, for example, a main body of a transformer mainly composed of an iron core and a winding, and at a predetermined reference temperature, a predetermined reference gas pressure, for example, higher than atmospheric pressure. The present invention relates to a gas leakage monitoring device for a gas-insulated electric device such as a gas-insulated transformer, which has a container in which an insulating gas is hermetically sealed under pressure.

[0002]

2. Description of the Related Art Generally, in gas-insulated electric equipment,
Insulating gas of appropriate pressure corresponding to the equipment temperature, eg SF
₆ is enclosed in a container to ensure insulation. But,
The gas pressure inside the container changes according to the temperature change, and the insulation strength inside the container changes according to the gas density.Therefore, the gas density inside the container is constantly controlled to maintain the desired dielectric strength. There is a need.

Since the gas density inside the container is proportional to the gas pressure inside the container when the temperature is constant, it is proposed to manage the gas pressure inside the container instead of managing the gas density inside the container. ing. That is, the gas pressure inside the container is detected along with the gas temperature inside the container, and the detected gas pressure is temperature-compensated with the detected gas temperature,
A method of managing the gas pressure inside the container to control the gas density inside the container has been proposed.

FIG. 5 shows a gas leakage monitoring apparatus for gas-insulated electric equipment. In the figure, 1 is an electric equipment main body which is a transformer main body mainly composed of an iron core and windings, and 2 is this electric equipment main body. And a container 4 made of a tank in which an insulating gas 3 as an insulating / cooling medium is enclosed at a reference gas pressure under a reference gas temperature and an upper protection tube provided at the upper part of the container. Reference numeral 5 denotes an upper temperature sensor provided inside the upper protection tube for detecting the temperature of the insulating gas 3 located at the upper portion of the container 2.
Is a lower protection tube provided in the lower part of the container 2, and 7 is provided in the lower protection tube 6, and a lower temperature for detecting the temperature of the insulating gas 3 located in the lower part of the container 2. A sensor, 8 is a gas pipe provided in communication with the container 2, and 9 is a pressure sensor which is provided in the gas pipe via a valve 10 and detects the pressure of the insulating gas 3 in the container 2.

Reference numeral 11 denotes upper side temperature information of the insulating gas 3 from the upper side temperature sensor 5, and lower side temperature sensor 7
From the pressure sensor 9 and the lower side temperature information of the insulating gas 3 from the pressure sensor 9 are received through the cable 12, and the calculation is performed based on the upper side temperature information, the lower side temperature information and the pressure information. An arithmetic unit for comparing and outputting signals calculates an average temperature of the insulating gas 3 on the basis of the upper temperature information and the lower temperature information, and a reference gas based on the average temperature, the reference gas temperature and the reference gas pressure. The temperature compensating gas pressure is calculated based on the temperature information and the reference gas pressure information, and the pressure information is compared with a predetermined alarm pressure range based on the calculated temperature compensating gas pressure. An alarm signal is output when the pressure is within the alarm pressure range. Reference numeral 13 denotes a calculation result of this calculation device, an upper temperature of the insulating gas 3 detected by the upper temperature sensor 5, a lower temperature of the insulating gas 3 detected by the lower temperature sensor 7, and The display device displays the pressure of the insulating gas 3 from the pressure sensor 9.

Next, the operation of the gas leakage monitoring apparatus for the gas-insulated electric equipment thus configured will be described. When a load is applied to a gas-insulated transformer, which is a gas-insulated electrical device,
The iron core and windings that compose the transformer body that is the electric device body 1 generate heat. The generated heat is transferred to the insulating gas 3, and the insulating gas 3 circulates in the container 2. Therefore, the temperature of the insulating gas 3 located above the container 2 is high, and the temperature of the insulating gas 3 located below it is low.

Therefore, the upper temperature sensor 5 detects the maximum temperature of the insulating gas 3 located above the container 2 and outputs it to the arithmetic unit 11 as the maximum temperature information θ _T , and the lower temperature sensor 7 detects the temperature of the container. The lowest point temperature of the insulating gas 3 located under 2 is detected and output to the arithmetic unit 11 as the lowest point temperature information θ _B. The arithmetic unit 11 which has received the highest point temperature information θ _T and the lowest point temperature information θ _B calculates the average temperature information θ _i of the insulating gas 3 based on the following equation (1). This arithmetic operation may be a simple arithmetic mean, or may be based on other suitable arithmetic expressions. θ _i = f (θ _T θ _B ) ・ ・ ・ ・ ・ ・ (1)

On the other hand, the relationship between the gas temperature (absolute temperature) and the gas pressure (absolute pressure) in the insulating gas 3 can be expressed by the following equation (2) according to Boyle-Charles' law. (P × V) / T = (P _s × V _s ) / T _s (2) Here, P is the pressure of the insulating gas 3 with respect to the measured absolute temperature T, and V is the measured absolute temperature T. The volume of the container 2 with respect to, P _s is the reference gas pressure of the absolute gas 3 with respect to the reference absolute temperature T _s ,
V _s is the reference volume of the container 2 with respect to the reference absolute temperature T _s .

By the way, in a gas-insulated transformer or the like, the container 2 in which the insulating gas 3 is enclosed is usually made of metal, so that even if the temperature changes, the change in the volume of the container 2 is negligibly small. It is a thing. Therefore, the above equation (2) can be transformed into the following equation (3). P / T = P _s / T _s (3) This equation (3) can be transformed into the following equation (4). P = P _s × {(273 + θ) / (273 + θ _s )} (4) where θ is the temperature of the insulating gas with respect to the absolute temperature T, and θ _s
Is the reference gas temperature with respect to the reference absolute temperature.

The relationship between the gas temperature θ and the gas pressure P according to the above equation (4) is that the reference gas temperature θ _s is 20 ° C., the reference gas pressure P _s is 2.2 kg / cm ² , and the insulating gas 3 is inside the container 2. When there is no gas leak in the container 2 when it is sealed in, the relationship of the straight line A shown in FIG. 6 is obtained. The gas pressure on the straight line A is the normal pressure with respect to the actual temperature θ _i , that is, the temperature compensation gas pressure _Pis . Then, the temperature compensation gas pressure P on the straight line A is calculated in consideration of the measurement error and the like.
_The alarm pressure (see the hatched portion B shown in FIG. 6) is set in the range of 0.3 to 0.4 kg / cm ² lower than _is .

Therefore, the arithmetic unit 11 calculates the insulating gas 3 based on the maximum temperature information θ _T from the upper temperature sensor 5 and the minimum temperature information θ _B from the lower temperature sensor 7.
Based on the average temperature information theta _i temperature compensated gas pressure P _IS (=
P _s × {(273 + θ _i ) / (273 + θ _s )}) is calculated to set the alarm pressure, and the insulating gas 3 input from the pressure sensor 9 is set.
The pressure information P _i is compared with the pressure information P _i, and an alarm is output when the pressure information P _i falls below the alarm pressure. The display means 13 displays the maximum temperature from the upper temperature sensor 5, the minimum temperature from the lower temperature sensor 7, and the gas pressure from the pressure sensor 9.

Further, in Japanese Laid-Open Patent Publication No. 62-160011, a gas pressure detector for detecting the pressure of the insulating gas inside the container, and a gas pressure detection signal from the gas pressure detector are used to indicate the gas pressure for each gas section. A change rate calculating means for calculating the change rate and generating an output signal when the change rate is equal to or more than a negative set change rate, and a display output means for outputting a display signal when the output signal from the change rate calculating means is generated. The control device of the gas-insulated switchgear provided is shown.

Further, Japanese Patent Laid-Open No. 63-28207 discloses a gas pressure detector for detecting the pressure of the insulating gas inside the container, a gas temperature detector for detecting the temperature of the insulating gas inside the container, and a gas pressure detector. Correction gas pressure derivation means for obtaining a correction gas pressure detection signal by correcting the gas pressure detection signal from the detector with the gas temperature detection signal from the gas temperature detector, and this correction gas pressure derivation means A gas having a comparison / determination means for comparing the amount of change in the corrected gas pressure detection signal obtained by the means with a preset gas pressure change amount alarm value and outputting an alarm according to the comparison result. A gas pressure monitor for an insulated switchgear is shown.

[0014]

However, in the conventional example shown in FIG. 5 described above, the alarm range B shown in FIG. 6 in which the gas pressure from the pressure sensor 9 is calculated by the calculation unit 11 is shown. Since the alarm is issued only when the following occurs, even if the insulating gas 3 leaks from the container 2,
Until the gas pressure from the pressure sensor 9 falls below the alarm range calculated by the arithmetic unit 11, the presence or absence of gas leak is not known, the discovery of gas leak is delayed, and there is not enough time to take measures against gas leak. There was a problem that a case occurred. In order to solve this problem, when the alarm range B shown in FIG. 6 _is brought close to the temperature compensating gas pressure P _is shown by the straight line A in FIG. 6, even if no gas leak occurs, the instrument error However, there is a problem that an alarm is issued due to an error in calculating the average temperature.

Further, in the one disclosed in Japanese Patent Laid-Open No. 62-160011, the gas pressure detection signal detected by the gas pressure detector is used as it is. Due to the temperature change of the insulating gas due to heat generation of the main body, it is not possible to calculate a highly accurate change rate of gas pressure,
It is easy to malfunction, and since it is known that a gas leak has occurred only after an alarm is issued, the discovery of a gas leak may be delayed, and there may be cases where there is not enough time to take measures against gas leaks. There was a problem that.

Further, in the one disclosed in Japanese Patent Laid-Open No. 63-28207, an alarm is issued according to the result of comparison between the amount of change in the correction gas pressure detection signal and a preset gas pressure change amount alarm value. Since this is output, there is a fear that if this alarm is issued, it is not necessary to take immediate measures or what kind of measures should be taken, and it will only call attention to mischief. Was caused.

The present invention has been made in view of the above-mentioned points, and it is possible to detect a gas leak of the insulating gas in the container at an early stage and to obtain a sufficient time margin for the countermeasure against the gas leak. The object is to obtain a gas leak monitoring device for equipment.

[0018]

According to a first aspect of the present invention, there is provided a gas leakage monitoring apparatus for gas-insulated electric equipment, wherein an electric equipment body is housed and insulated at a reference gas pressure under a reference gas temperature. The pressure detecting means for detecting the pressure of the insulating gas in the container in which the gas is sealed, the temperature detecting means for detecting the temperature of the insulating gas in the container, the time measuring means for measuring the time, and the pressure detecting means The pressure information, the temperature information from the temperature detecting means, and the time information from the time measuring means are input, and the input pressure information and temperature information and the reference gas temperature and the reference gas temperature information and the reference gas pressure information based on the reference gas pressure are input. Calculation of calculating the reference temperature-converted gas pressure based on the calculated temperature, and calculating the gas pressure decrease rate based on the calculated reference temperature-converted gas pressure and the time information from the input time measuring means. And the gas pressure decrease rate calculated by the calculating means and the specified gas pressure decrease rate, and outputs an alarm signal when the gas pressure decrease rate calculated by the calculating means exceeds the specified gas pressure decrease rate. The alarm signal output means and the display means for receiving the gas pressure decrease rate calculated by the calculating means and displaying the gas pressure decrease rate are provided.

In the gas leakage monitoring apparatus for gas-insulated electric equipment according to the second aspect of the present invention, the electric equipment main body is housed and the insulating gas is sealed at the reference gas pressure under the reference gas temperature. Pressure detecting means for detecting the pressure of the insulating gas in the container, temperature detecting means for detecting the temperature of the insulating gas in the container, time measuring means for measuring time, pressure information from the pressure detecting means, temperature detecting means The temperature information from the and the time information from the time measuring means are input, and the reference temperature conversion gas is based on the input pressure information and temperature information, the reference gas temperature, the reference gas temperature information based on the reference gas pressure, and the reference gas pressure information. The pressure is calculated, the gas pressure decrease rate is calculated based on the calculated reference temperature conversion gas pressure and the time information from the input time measuring means, and the calculated pressure is calculated. Calculation means for calculating the remaining time up to the allowable lower limit gas pressure based on the calculated pressure decrease gas pressure and the calculated reference temperature-converted gas pressure, and comparing the remaining time calculated by this calculating means with the specified remaining time, An alarm signal output means for outputting an alarm signal when the remaining time calculated by the means becomes equal to or less than the specified remaining time is provided.

[0020]

In the first aspect of the present invention, the calculating means for calculating the gas pressure decrease rate calculates the reference temperature converted gas pressure, and the gas pressure decrease rate is calculated based on the reference temperature converted gas pressure. When the gas pressure reduction rate calculated by the calculation means by the calculation means is equal to or higher than the specified gas pressure reduction rate, an alarm signal is generated to promptly take measures against gas leakage, and the display means is calculated by the calculation means. It works to display the gas pressure drop rate that has been displayed and to take appropriate measures against gas leaks.

In the second aspect of the present invention, the calculating means for calculating the gas pressure decrease rate calculates the reference temperature converted gas pressure, and the gas pressure decrease rate is calculated based on the reference temperature converted gas pressure. The remaining time until the allowable lower limit gas pressure is calculated based on the calculated gas pressure decrease rate and the calculated reference temperature converted gas pressure, and the remaining time calculated by the alarm signal generating means by the calculating means. When the remaining time becomes less than the specified remaining time, an alarm signal will be generated to promptly call for gas leak countermeasures so that appropriate gas leak countermeasures can be taken.

[0022]

1 and 2 show an embodiment of the present invention. In FIG. 1, the same reference numerals as those in the conventional example shown in FIG. 5 designate the same or corresponding parts.
Reference numeral 14 is a time measuring means for measuring time, 15 is upper temperature information of the insulating gas 3 from the upper temperature sensor 5, lower temperature information of the insulating gas 3 is from the lower temperature sensor 7, and pressure is pressure detecting means. The cable 1 receives the pressure information of the insulating gas 3 from the sensor 9 and the time information from the time measuring means 14.
2 is an arithmetic unit that receives the data via the upper side temperature information, the lower side temperature information, the pressure information and the time information, and performs a calculation / comparison / signal output. ing.

In FIG. 2, 15a is a time measuring means 14.
Based on the lower temperature information of the upper temperature information of the insulating gas 3 from the upper temperature sensor 5 and the lower temperature information of the insulating gas 3 from the lower temperature sensor 7 at a predetermined time The average temperature calculating means for calculating the average temperature information θ _i of the insulating gas 3 constitutes the temperature detecting means for detecting the temperature of the insulating gas in the container 2 by the upper temperature sensor 5 and the lower temperature sensor 7. It is a thing. 15b
Is the average temperature information θ _i of the insulating gas 3 and the pressure information P _i of the insulating gas 3 from the pressure sensor 9 in the predetermined time of the time measuring means 14 calculated by the average temperature calculating means 15 a.
Is input and the reference temperature conversion gas pressure information P _ci is calculated by the following expression (5). P _ci = P _i × {(273 + θ _s ) / (273 + θ _i )} ···· (5)

The reference temperature-converted gas pressure calculation means 15b receives the reference temperature-converted gas pressure information P _ci and the average temperature information θ _i of the insulating gas 3 calculated by the average temperature calculation means 15a. The reference gas pressure P _si (point on the straight line A shown in FIG. 6) with respect to the average temperature θ _i of the gas 3 is calculated, and the calculated reference gas pressure information P
By comparing _si with the reference temperature-converted gas pressure information P _ci and outputting an output signal when the reference temperature-converted gas pressure information P _ci becomes equal to or lower than the reference gas pressure information P _si , the output signal is output. The reference temperature converted gas pressure information P _ci from the reference temperature converted gas pressure calculating means 15b is stored in the storage means 16 which is a semiconductor memory in time series with the time from the time measuring means 14.

Reference numeral 15d denotes the reference temperature conversion gas pressure information P _ci from the plurality of reference temperature conversion gas pressure calculation means 15b stored in the storage means 16 after the output signal is output by the pressure comparison means 15c and the above-mentioned. Decrease speed calculation means for performing statistical processing based on the time T _i from the time measuring means 14 to calculate the reference temperature converted gas pressure decrease speed V _p , and 15e is a reference temperature converted gas pressure decrease from this decrease speed calculating means 15d. The speed V _p is compared with the specified gas pressure decrease speed V _s in the average temperature information θ _i, and when the reference temperature converted gas pressure decrease speed V _p is equal to or higher than the specified gas pressure decrease speed V _s , the alarm means 17 such as an alarm is provided. It is a gas pressure drop speed comparison means which is an alarm signal output means for outputting an alarm signal.

Reference numeral 15f is an insulating gas in the container 2 based on the reference temperature conversion gas pressure information P _ci from the reference temperature conversion gas pressure calculation means 15b and the reference temperature conversion gas pressure decrease rate V _p from the decrease rate calculation means 15d. The remaining time calculation means for predicting and calculating the remaining time T _A until reaching the permissible lower limit gas pressure of 3, and 15 g is the remaining time T _A from the remaining time calculation means 15 f and the specified remaining time T _s (for example, as a countermeasure against gas leakage, (Sufficient time to perform), and when the remaining time T _A becomes equal to or less than the specified remaining time T _s , the remaining time comparison means serves as an alarm signal output means for outputting an alarm signal to the alarm means 17.

In the arithmetic unit 15, the pressure information from the pressure sensor 9, the temperature information from the temperature detecting unit and the time measuring unit are constituted by the reference temperature conversion gas pressure calculating unit 15b, the pressure comparing unit 15c and the decreasing speed calculating unit 15d. The time information from 14 is input, and the reference temperature conversion gas pressure is calculated based on the input pressure information and temperature information, and the reference gas temperature and the reference gas temperature information based on the reference gas pressure and the reference gas pressure information. The calculation means constitutes a gas pressure decrease rate on the basis of the calculated reference temperature converted gas pressure and the inputted time information from the time measuring means.

Further, in the calculation device 15, the reference temperature conversion gas pressure calculation means 15b, the pressure comparison means 15c, the decreasing speed calculation means 15d and the remaining time calculation means 15f are used to obtain pressure information from the pressure sensor 9 and temperature detection means. The temperature information and the time information from the time measuring means 14 are input, and the reference temperature conversion gas is generated based on the input pressure information and temperature information, the reference gas temperature, the reference gas temperature information based on the reference gas pressure, and the reference gas pressure information. Calculate the pressure,
The gas pressure decrease rate is calculated based on the calculated reference temperature converted gas pressure and the input time information from the time measuring means 14, and the calculated gas pressure decrease rate and the calculated reference temperature converted gas are calculated. The calculation means is configured to calculate the remaining time up to the allowable lower limit gas pressure based on the pressure.

In FIG. 1, reference numeral 18 denotes the upper side temperature of the insulating gas 3 from the upper side temperature sensor 5 according to the upper side temperature information θ _T , and pressure information P of the insulating gas 3 from the pressure sensor 9.
Gas pressure calculating means 15 based on _i based on pressure and reference temperature
Reference temperature converted gas pressure based on the reference temperature converted gas pressure information P _ci calculated in b, gas pressure decrease rate V _p calculated by the decrease rate calculation means 15d, and alarm signal from the gas pressure decrease speed comparison means 15e warning display based on a display means for displaying a warning display based on the warning signal from the computed remaining time T _a and the remaining time comparison means 15g in the remaining time calculating unit 15f.

Next, the operation of the gas leakage monitoring apparatus for the gas-insulated electric equipment thus configured will be described with reference to the flowchart shown in FIG. When a load is applied to a gas-insulated transformer that is a gas-insulated electric device, the iron core and windings that form the transformer body that is the electric device body 1 generate heat. When the heat thus generated is transferred to the insulating gas 3 in the container 2, first, in step S1, the upper temperature sensor 5 detects the maximum temperature of the insulating gas 3 located above the container 2. The temperature sensor 7 detects and outputs to the arithmetic unit 15 the highest point temperature information θ _T , and the lower temperature sensor 7 detects the lowest point temperature of the insulating gas 3 located at the bottom of the container 2 and informs the arithmetic unit 15 of the lowest point temperature information θ _T. Output as _B. The average temperature calculation means 15a of the calculation device 15 which has received the maximum temperature information θ _T and the minimum temperature information θ _B calculates the average temperature information θ _i of the insulating gas 3 based on the above equation (1). Then, in step S2, the maximum point temperature based on the maximum point temperature information θ _T from the upper temperature sensor 5 is displayed on the display means 18, and the process proceeds to step S3.

At step S3, the pressure sensor 9 moves to the container 2
The pressure of the insulating gas 3 therein is detected and taken into the arithmetic unit 15 as pressure information P _i , and in step S4, the pressure is displayed on the display means 18 based on this pressure information P _i . In step S5, the reference temperature conversion gas pressure calculating means 15b is used to input the average temperature information θ _i of the insulating gas 3 and the insulation from the pressure sensor 9 in the predetermined time of the time measuring means 14 calculated by the input average temperature calculating means 15a. Based on the pressure information P _i of the gas 3, the reference temperature conversion gas pressure information P _ci is calculated by the above equation (5), and step S
At 6, the calculated reference temperature converted gas pressure information P _ci is displayed by the display means 18.

In step S7, the pressure comparison means 15c
Is inputted with the reference temperature converted gas pressure information P _ci from the reference temperature converted gas pressure calculating means 15b and the average temperature information θ _i of the insulating gas 3 calculated by the average temperature calculating means 15a. The reference gas pressure P _si with respect to the temperature θ _i is calculated, and the calculated reference gas pressure information P
_{The si} is compared with the reference temperature conversion gas pressure information P _ci . If the reference temperature conversion gas pressure information P _ci is equal to or higher than the reference gas pressure information P _si , the process returns to step S1. When the reference temperature converted gas pressure information P _ci becomes less than the reference gas pressure information P _si , the pressure comparison means 15c causes the reference temperature converted gas pressure calculation means 15b.
The output signal is output to and the process proceeds to step S8.

In step S8, the reference temperature converted gas pressure calculating means 15b receives the output signal from the pressure comparing means 15c, and the reference temperature converted gas pressure information P _ci is stored in the storage means 16 together with the time T _i from the time measuring means 14. Memorized in. In step S8, the time T _i and the reference temperature conversion gas pressure information P _ci are stored in the storage means 16 in time series with i + 1 as i + 1. Next, the process proceeds to step S9, and the lowering speed calculation means 15d uses the reference temperature conversion gas pressure information P _ci from the plurality of reference temperature conversion gas pressure calculation means 15b stored in the storage means 16 and the time measurement means 14 from the time measurement means 14. The statistical processing is performed based on the time T _i , and the reference temperature conversion gas pressure decrease rate V _p is calculated as shown in FIG. The calculated reference temperature conversion gas pressure decrease rate V _p is displayed on the display means 18 in step S11.

Then, in step S12, the remaining time calculation means 15f causes the reference temperature conversion gas pressure information P _ci from the reference temperature conversion gas pressure calculation means 15b and the reference temperature conversion gas pressure decrease rate from the decrease rate calculation means 15d. Based on V _p , the remaining time T _A until the insulating gas 3 in the container 2 reaches the allowable lower limit gas pressure is predicted and calculated, and the calculated remaining time T _A is displayed on the display means 18 in step S12. ..
Next, comparison in step S13, the gas pressure drop speed comparing unit 15e is a defined gas pressure drop velocity V _s a reference temperature conversion gas pressure drop velocity V _p from lowering speed calculating means 15d in the average temperature information theta _i To do. If the reference temperature conversion gas pressure decrease rate V _p is less than the specified gas pressure decrease rate V _s , the process returns to step S1. When the reference temperature-converted gas pressure decrease rate V _p becomes equal to or higher than the specified gas pressure decrease rate V _s , the process proceeds to step S14, an alarm signal is output to the alarm means 17 such as an alarm to give an alarm, and the display means 18 is also alarmed. Display based on signal.

After that, the procedure proceeds to step S15, where the remaining time comparing means 15g outputs the remaining time T from the remaining time calculating means 15f.
_A is compared with the specified remaining time T _s . When the remaining time T _A is longer than the specified remaining time T _s , the process returns to step S1. When the remaining time T _A becomes equal to or less than the specified remaining time T _s , the process proceeds to step S16, an alarm signal is output to the alarm means 17 to issue an alarm, and the display means 18 displays the alarm signal based on the alarm signal.
Return to step S1. After that, the same operation as described above is repeated.

In the gas leakage monitoring apparatus for gas insulated electric equipment constructed as described above, the gas pressure decrease rate V _p
Generates a warning signal when V becomes equal to or higher than the prescribed gas pressure decrease rate V _s , and an alarm signal when remaining time T _A becomes equal to or less than the prescribed remaining time T _s , so that gas leak countermeasures can be promptly evoked. Moreover, since the display means 18 displays the gas pressure decrease rate V _p and the remaining time T _A , the gas pressure decrease rate V _p and the remaining time T _A can be constantly monitored, and an appropriate gas leakage countermeasure can be taken. It is a thing.

In the above embodiment, the display means 1
Reference numeral 8 denotes a gas pressure calculation means for converting the upper temperature based on the upper temperature information θ _T of the insulating gas 3 from the upper temperature sensor 5, the pressure based on the pressure information P _i of the insulating gas 3 from the pressure sensor 9, and the reference temperature conversion gas pressure. 15b, the reference temperature conversion gas pressure based on the reference temperature conversion gas pressure information P _ci , the gas pressure reduction rate V _p calculated by the reduction rate calculation means 15d, and the alarm signal from the gas pressure reduction rate comparison means 15e. Although the alarm display based on the alarm display, the remaining time T _A calculated by the remaining time calculation means 15f, and the alarm display based on the alarm signal from the remaining time comparison means 15g are separately displayed, there are few display items. When the display means 18 is used, the pressure information P of the insulating gas 3 from the pressure sensor 9 is always supplied.
_The pressure based on _i may be displayed, and the other display may be switched and displayed when necessary.

An alarm signal is generated when the gas pressure decrease speed V _p is equal to or higher than the specified gas pressure decrease speed V _s , and an alarm signal is generated when the remaining time T _A is equal to or less than the specified remaining time T _s. However, an alarm signal is generated when the gas pressure decrease rate V _p is equal to or more than the specified gas pressure decrease rate V _s , and when the remaining time T _A is equal to or less than the specified remaining time T _s. An alarm signal may be generated, and the gas pressure decrease rate V _p becomes equal to or higher than the specified gas pressure decrease rate V _s (one or more times), and the remaining time T _A is the specified remaining time T _s. The alarm signal may be generated only after the following (one or more times). By doing so, a more reliable device can be obtained.

[0039]

According to the first aspect of the present invention, the pressure information from the pressure detecting means, the temperature information from the temperature detecting means and the time information from the time measuring means are input, and the input pressure information and temperature information are stored. A calculating means for calculating a reference temperature converted gas pressure based on the reference gas temperature information and the reference gas pressure information, and a gas pressure decrease rate based on the reference temperature converted gas pressure and time information, and the calculating means. An alarm signal output means for outputting an alarm signal when the calculated gas pressure decrease rate is equal to or higher than the specified gas pressure decrease rate; and a display means for displaying the gas pressure decrease rate calculated by the calculating means. As a result, an alarm is issued based on the gas pressure drop rate and the gas pressure drop rate can be constantly monitored by the display means, so that a gas leak can be detected early and promptly. Take a gas leakage countermeasure, those having the effect that it is highly reliable gas leakage monitoring.

In a second aspect of the present invention, the pressure information from the pressure detecting means, the temperature information from the temperature detecting means and the time information from the time measuring means are input, and the input pressure information and temperature information and the reference gas are input. The reference temperature conversion gas pressure is calculated based on the temperature information and the reference gas pressure information, the gas pressure decrease rate is calculated based on the calculated reference temperature conversion gas pressure and time information, and the calculated gas is calculated. A calculation means for calculating the remaining time up to the allowable lower limit gas pressure based on the pressure decrease rate and the calculated reference temperature conversion gas pressure, and the remaining time calculated by this calculation means is compared with the specified remaining time to calculate the remaining time. Since the alarm signal output means for outputting an alarm signal when the remaining time calculated by the means becomes less than the specified remaining time is provided, the gas leak countermeasures are planned and the time is spared. Implementation can, and has the effect that it is highly reliable gas leakage monitoring.

[Brief description of drawings]

FIG. 1 is a sectional front view showing an embodiment of the present invention.

FIG. 2 is a block diagram showing an arithmetic unit in one embodiment of the present invention.

FIG. 3 is a flowchart showing a processing procedure in an embodiment of the present invention.

FIG. 4 is a diagram illustrating a time and a reference gas pressure P _si , a reference temperature conversion gas pressure information P _ci , a specified gas pressure decrease rate V _s , and a reference when a gas leak of an insulating gas 3 occurs in an embodiment of the present invention. Temperature conversion gas pressure decrease rate V _p , remaining time T _A ,
Diagram showing the relationship between the specified remaining time T _s and the allowable lower limit gas pressure.

FIG. 5 is a cross-sectional front view showing a conventional gas leakage monitoring device for gas insulated electrical equipment.

FIG. 6 is a diagram showing a relationship among a gas temperature, a gas pressure, and an alarm pressure range in a gas leak monitoring device for a conventional gas-insulated electric device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Electric equipment main body 2 Container 3 Insulating gas 5 Upper temperature sensor 7 Lower temperature sensor 9 Pressure sensor 14 Time measuring means 15 Computing device 18 Display means

[Procedure amendment]

[Submission date] August 17, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be amended] Claims

[Correction method] Change

[Correction content]

[Claims]

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0005

[Correction method] Change

[Correction content]

Reference numeral 11 denotes upper side temperature information of the insulating gas 3 from the upper side temperature sensor 5, and lower side temperature sensor 7
From the pressure sensor 9 and the lower side temperature information of the insulating gas 3 from the pressure sensor 9 are received through the cable 12, and the calculation is performed based on the upper side temperature information, the lower side temperature information and the pressure information. in a calculation device for performing such comparison and signal output, based on the upper temperature information and the lower temperature information, thereby calculating the average temperature of the insulating gas 3, the average temperature and the reference gas temperature soil paper and the reference gas pressure The temperature compensating gas pressure is calculated based on the information, and the pressure information is compared with a predetermined alarm pressure range based on the calculated temperature compensating gas pressure, and the pressure information is equal to or less than the warning pressure range. And an alarm signal is output. Reference numeral 13 denotes a calculation result of this calculation device, an upper temperature of the insulating gas 3 detected by the upper temperature sensor 5, a lower temperature of the insulating gas 3 detected by the lower temperature sensor 7, and The display device displays the pressure of the insulating gas 3 from the pressure sensor 9.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction content]

On the other hand, the relationship between the gas temperature (absolute temperature) and the gas pressure (absolute pressure) in the insulating gas 3 can be expressed by the following equation (2) according to Boyle-Charles' law. (P × V) / T = (P _s × V _s ) / T _s (2) Here, P is the pressure of the insulating gas 3 with respect to the measured absolute temperature T, and V is the measured absolute temperature T. volume of the container 2 against, P _s is the reference gas pressure insulation gas 3 with respect to the reference absolute temperature T _s,
V _s is the reference volume of the container 2 with respect to the reference absolute temperature T _s .

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0009

[Correction method] Change

[Correction content]

By the way, in a gas-insulated transformer or the like, the container 2 in which the insulating gas 3 is enclosed is usually made of metal, so that even if the temperature changes, the change in the volume of the container 2 is negligibly small. It is a thing. Therefore, the above equation (2) can be transformed into the following equation (3). P / T = P _s / T _s (3) This equation (3) can be transformed into the following equation (4). _{P = P s × {(273} + θ) / (273 + θ s)} ······· (4) where, theta Celsius temperature of the insulating gas to the absolute temperature T,
theta _s is the reference gas Celsius <br/> temperature of the insulating gas with respect to the reference absolute temperature T _s.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0011

[Correction method] Change

[Correction content]

Therefore, the arithmetic unit 11 calculates the insulating gas 3 based on the maximum temperature information θ _T from the upper temperature sensor 5 and the minimum temperature information θ _B from the lower temperature sensor 7.
Based on the average temperature information theta _i temperature compensated gas pressure P _IS (=
_{P s × {(273 + θ} i) / (273 + θ s)}) is calculated and compared with the pressure information P _i of the insulating gas 3 input from the pressure sensor 9, the pressure information P _i is below the alarm pressure It outputs an alarm. The display means 13 displays the maximum temperature from the upper temperature sensor 5, the minimum temperature from the lower temperature sensor 7, and the gas pressure from the pressure sensor 9.

[Procedure correction 6]

[Document name to be amended] Statement

[Correction target item name] 0014

[Correction method] Change

[Correction content]

[0014]

However, in the conventional example shown in FIG. 5, the alarm is issued only when the gas pressure from the pressure sensor 9 becomes equal to or lower than the alarm pressure B. Even if there is a gas leak of the insulating gas 3 from 2, the presence or absence of the gas leak is not known until the gas pressure from the pressure sensor 9 falls below the alarm range calculated by the calculation device 11, and the discovery of the gas leak is delayed. However, there is a problem in that there may not be sufficient time to take measures against gas leakage. In order to solve this problem, when the alarm range B shown in FIG. 6 is brought close to the normal gas pressure shown by the straight line A in FIG. 6, even if no gas leak occurs, the error of the instrument and the average temperature However, there is a problem in that an alarm is issued due to a calculation error or the like.

[Procedure Amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction content]

[0018]

According to a first aspect of the present invention, there is provided a gas leakage monitoring apparatus for gas-insulated electric equipment, wherein an electric equipment body is housed and insulated at a reference gas pressure under a reference gas temperature. The pressure detecting means for detecting the pressure of the insulating gas in the container in which the gas is sealed, the temperature detecting means for detecting the temperature of the insulating gas in the container, the time measuring means for measuring the time, and the pressure detecting means pressure information, the time information from the temperature information and time measuring means from the temperature detecting means is inputted, the reference gas temperature information according to the input pressure information and the temperature information and the reference gas <br/> temperature soil paper and the reference gas pressure And the reference temperature converted gas pressure is calculated based on the reference gas pressure information, and the gas pressure decrease rate is calculated based on the calculated reference temperature converted gas pressure and the time information from the input time measuring means. And a gas pressure decrease rate calculated by this calculating means and the specified gas pressure decrease rate, and when the gas pressure decrease rate calculated by the calculating means becomes equal to or higher than the specified gas pressure decrease rate, an alarm signal is issued. Is provided, and a display unit for receiving the gas pressure reduction rate calculated by the calculation unit and displaying the gas pressure reduction rate is provided.

[Procedure Amendment 8]

[Document name to be amended] Statement

[Name of item to be corrected] 0019

[Correction method] Change

[Correction content]

In the gas leakage monitoring apparatus for gas-insulated electric equipment according to the second aspect of the present invention, the electric equipment main body is housed and the insulating gas is sealed at the reference gas pressure under the reference gas temperature. Pressure detecting means for detecting the pressure of the insulating gas in the container, temperature detecting means for detecting the temperature of the insulating gas in the container, time measuring means for measuring time, pressure information from the pressure detecting means, temperature detecting means time information from the temperature information and the time measuring means from is input, based according to the input pressure information and the temperature information and the reference gas temperature soil paper and the reference gas pressure in the reference gas temperature information and the reference gas pressure information criterion The temperature-converted gas pressure is calculated, and the gas pressure decrease rate is calculated based on the calculated reference temperature-converted gas pressure and the time information from the input time measuring means,
Moreover, the calculating means for calculating the remaining time to the allowable lower limit gas pressure based on the calculated gas pressure decrease rate and the calculated reference temperature converted gas pressure, and the remaining time calculated by the calculating means and the specified remaining time. An alarm signal output means is provided for outputting an alarm signal when the remaining time calculated by the calculating means in comparison with the time becomes equal to or less than the specified remaining time.

[Procedure Amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0024

[Correction method] Change

[Correction content]

Reference numeral 15c is the reference temperature conversion gas pressure information P _ci from the reference temperature conversion gas pressure calculating means 15b and the reference gas.
The output signal is output by the output comparing means that compares the reference gas pressure information P _s at the temperature θ _s and outputs the output signal when the reference temperature conversion gas pressure information P _ci becomes equal to or lower than the reference gas pressure information P _s. The reference temperature converted gas pressure calculating means 15b stores the reference temperature converted gas pressure information P _ci together with the time from the time measuring means 14 in time series in the storage means 16 composed of a semiconductor memory.

[Procedure Amendment 10]

[Document name to be amended] Statement

[Name of item to be corrected] 0025

[Correction method] Change

[Correction content]

Reference numeral 15d denotes the reference temperature conversion gas pressure information P _ci from the plurality of reference temperature conversion gas pressure calculation means 15b stored in the storage means 16 after the output signal is output by the pressure comparison means 15c and the above-mentioned. Decrease speed calculation means for performing statistical processing based on the time T _i from the time measuring means 14 to calculate the reference temperature converted gas pressure decrease speed V _p , and 15e is a reference temperature converted gas pressure decrease from this decrease speed calculating means 15d. velocity V _p and the provisions gas pressure drop velocity V _s
When the reference temperature-converted gas pressure decrease rate V _p becomes equal to or higher than the specified gas pressure decrease rate V _s , the gas pressure decrease rate comparison means becomes an alarm signal output means for outputting an alarm signal to the alarm means 17 such as an alarm. is there.

[Procedure Amendment 11]

[Document name to be amended] Statement

[Name of item to be corrected] 0027

[Correction method] Change

[Correction content]

In the arithmetic unit 15, the pressure information from the pressure sensor 9, the temperature information from the temperature detecting unit and the time measuring unit are constituted by the reference temperature conversion gas pressure calculating unit 15b, the pressure comparing unit 15c and the decreasing speed calculating unit 15d. time information from 14 is input, and the pressure information and the temperature information inputted, calculates a reference temperature conversion gas pressure based on the reference gas temperature soil report and reference gas pressure information, the calculated reference temperature conversion The calculating means constitutes the gas pressure decrease rate based on the gas pressure and the time information from the input time measuring means.

[Procedure Amendment 12]

[Document name to be amended] Statement

[Correction target item name] 0028

[Correction method] Change

[Correction content]

Further, in the calculation device 15, the reference temperature conversion gas pressure calculation means 15b, the pressure comparison means 15c, the decreasing speed calculation means 15d and the remaining time calculation means 15f are used to obtain pressure information from the pressure sensor 9 and temperature detection means. time information from the temperature information and the time measuring means 14 is input, and the pressure information and the temperature information input, the reference gas temperature
Calculating a reference temperature conversion gas pressure on the basis of the information and the reference gas pressure information, calculating the gas pressure drop rate based on the time information from the time measuring means 14 for the filled in computed reference temperature conversion gas pressure In addition, the calculating means is configured to calculate the remaining time to the allowable lower limit gas pressure based on the calculated gas pressure decrease rate and the calculated reference temperature-converted gas pressure.

[Procedure Amendment 13]

[Document name to be amended] Statement

[Name of item to be corrected] 0032

[Correction method] Change

[Correction content]

In step S7, the pressure comparison means 15c
Is based on the reference temperature conversion gas pressure information P _ci from the reference temperature conversion gas pressure calculation means 15b and the reference gas temperature θ _s .
The quasi gas pressure information P _s is compared. If the reference temperature conversion gas pressure information P _ci is equal to or higher than the reference gas pressure information P _s , the process returns to step S1. Further, when the reference temperature conversion gas pressure information P _ci becomes less than the reference gas pressure information P _s , the pressure comparison means 15c.
Outputs an output signal to the reference temperature conversion gas pressure calculating means 15b and proceeds to step S8.

[Procedure Amendment 14]

[Document name to be amended] Statement

[Correction target item name] 0033

[Correction method] Change

[Correction content]

In step S8, the reference temperature converted gas pressure calculating means 15b receives the output signal from the pressure comparing means 15c, and the reference temperature converted gas pressure information P _ci is stored in the storage means 16 together with the time T _i from the time measuring means 14. Memorized in. In step S8, the time T _i and the reference temperature conversion gas pressure information P _ci are stored in the storage means 16 in time series with i + 1 as i + 1. Next, the process proceeds to step S9, and the lowering speed calculation means 15d uses the reference temperature conversion gas pressure information P _ci from the plurality of reference temperature conversion gas pressure calculation means 15b stored in the storage means 16 and the time measurement means 14 from the time measurement means 14. The statistical processing is performed based on the time T _i , and the reference temperature conversion gas pressure decrease rate V _p is calculated as shown in FIG. The calculated reference temperature conversion gas pressure decrease rate V _p is displayed on the display means 18 in step S10 .

[Procedure Amendment 15]

[Document name to be amended] Statement

[Correction target item name] 0034

[Correction method] Change

[Correction content]

Then, in step S11 , the remaining time calculation means 15f causes the reference temperature conversion gas pressure information P _ci from the reference temperature conversion gas pressure calculation means 15b and the reference temperature conversion gas pressure decrease rate from the decrease rate calculation means 15d. Based on V _p , the remaining time T _A until the insulating gas 3 in the container 2 reaches the allowable lower limit gas pressure is predicted and calculated, and the calculated remaining time T _A is displayed on the display means 18 in step S12. ..
Next, in step S13, the gas pressure drop speed comparing unit 15e compares a reference temperature conversion gas pressure drop velocity V _p and the provisions gas pressure drop velocity V _s of the reduced speed calculating means 15d. If the reference temperature conversion gas pressure decrease rate V _p is less than the specified gas pressure decrease rate V _s , the process proceeds to step S15.
When the reference temperature-converted gas pressure decrease rate V _p becomes equal to or higher than the specified gas pressure decrease rate V _s , the process proceeds to step S14, an alarm signal is output to the alarm means 17 such as an alarm to give an alarm, and the display means 18 is also alarmed. Display based on signal.

[Procedure 16]

[Document name to be amended] Statement

[Name of item to be corrected] Fig. 4

[Correction method] Change

[Correction content]

FIG. 4 is a diagram illustrating a time and reference gas pressure P _s , reference temperature conversion gas pressure information P _ci , specified gas pressure decrease rate V _s , and reference when the insulating gas 3 leaks in one embodiment of the present invention. Temperature conversion gas pressure decrease rate V _p , remaining time T _A ,
Diagram showing the relationship between the specified remaining time T _s and the allowable lower limit gas pressure.

[Procedure Amendment 17]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 2

[Correction method] Change

[Correction content]

[Fig. 2]

[Procedure 18]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 3

[Correction method] Change

[Correction content]

[Figure 3]

[Procedure Amendment 19]

[Document name to be corrected] Drawing

[Name of item to be corrected] Fig. 4

[Correction method] Change

[Correction content]

[Figure 4]

Claims (2)

[Claims] 1. A pressure detecting means for detecting a pressure of the insulating gas in a container in which an electric device main body is housed and an insulating gas is sealed at a reference gas pressure under a reference gas temperature, in the container. The temperature detecting means for detecting the temperature of the insulating gas, the time measuring means for measuring time, the pressure information from the pressure detecting means, the temperature information from the temperature detecting means and the time information from the time measuring means are input. Calculating the reference temperature conversion gas pressure based on the input pressure information and temperature information, the reference gas temperature and the reference gas temperature information based on the reference gas pressure, and the reference gas pressure information, and converting the calculated reference temperature. Calculating means for calculating the gas pressure decrease rate based on the gas pressure and the time information inputted from the time measuring means, and the gas pressure decrease rate calculated by this calculating means. Compared with the specified gas pressure drop rate,
When the gas pressure decrease rate calculated by the calculation means becomes equal to or higher than the specified gas pressure decrease rate, an alarm signal output means for outputting an alarm signal, and the gas pressure decrease rate calculated by the calculation means are received. A gas leak monitoring device for gas-insulated electrical equipment, comprising a display means for displaying the rate of decrease. 2. A pressure detecting means for detecting the pressure of the insulating gas in a container in which the electric equipment main body is housed and the insulating gas is sealed at the reference gas pressure under the reference gas temperature, in the container. The temperature detecting means for detecting the temperature of the insulating gas, the time measuring means for measuring time, the pressure information from the pressure detecting means, the temperature information from the temperature detecting means and the time information from the time measuring means are input. Calculating the reference temperature conversion gas pressure based on the input pressure information and temperature information, the reference gas temperature and the reference gas temperature information based on the reference gas pressure, and the reference gas pressure information, and converting the calculated reference temperature. The gas pressure decrease rate is calculated on the basis of the gas pressure and the inputted time information from the time measuring means, and the calculated gas pressure decrease rate and the calculated basis are calculated. Calculating means for calculating the remaining time to the allowable lower limit gas pressure based on the quasi-temperature converted gas pressure, comparing the remaining time calculated by this calculating means with the specified remaining time,
A gas leak monitoring device for gas-insulated electrical equipment, comprising an alarm signal output means for outputting an alarm signal when the remaining time calculated by the above-mentioned calculating means becomes equal to or less than a specified remaining time.