JPH08247887A - Gas pressure monitor device for gas insulating equipment - Google Patents

Abstract

PURPOSE: To provide the gas pressure monitor device for a gas insulating equipment, which can accurately and quickly judge a cause for fluctuation in gas pressure. CONSTITUTION: The inside of a grounding metallic container 1 is divided by each insulating spacer 10 into gas blocks S1 , S2 ,... so as to be formed up. Respective housing boxes 72 are disposed in the vicinities of the respective gas blocks S1 , S2 ,..., and a gas pressure sensor 72 is disposed in each housing box 72. And the gas block S1 is connected to the gas pressure sensor 73 through a gas pipeline 70 and a gas valve 71. A gas temperature detecting section as a gas temperature detecting means within the gas pipeline 70 is provided for the partitioning film of the gas pressure sensor 73. And the gas temperature detecting section is connected to an electronic circuit which outputs not only gas pressure but also gas temperature as electric signals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a preventive maintenance system and a failure applied to the confirmation and monitoring of the reliability of a gas-insulated equipment in which a charging section is compactly housed in a grounded metal container containing an insulating gas. The present invention relates to a gas pressure monitoring device used as a point locating system.

[0002]

2. Description of the Related Art In recent years, the amount of power supply in urban areas has been increasing, but on the other hand, it has become more and more difficult to secure a site for substation equipment due to soaring land prices. Under these circumstances,
Gas insulation equipment, which is excellent in environmental resistance and compactness, is essential for enhancing substation equipment.

This gas-insulated device uses an insulating gas such as SF ₆ gas which is excellent in insulation and arc extinguishing property,
This is a device in which substation equipment such as a circuit breaker is housed and arranged in a sealed grounded metal container. Here, an example of a typical gas insulation device will be specifically described with reference to the layout diagram shown in FIG. 9.

In FIG. 9, reference numeral 1 denotes a pressure-resistant metal container at ground potential, which is generally called a ground metal container. A lightning arrester 2, a transformer 3, a grounding switch 4, a disconnector 5, a current transformer 6, a circuit breaker 7 and a busbar 8 are housed in the grounded metal container 1 as an electric power applying section. Further, an insulating gas 9 such as SF ₆ gas is sealed in the grounded metal container 1, and the grounded metal container 1 and the power applying unit are electrically insulated by this insulating gas 9.

On the other hand, in the grounded metal container 1, insulating spacers 10a to 10d for supporting the busbars 8 are provided at appropriate intervals, and these insulating spacers 10a are provided.
The mechanical strength and dielectric strength of the bus bar 8 are maintained by 10d. In addition, each insulating spacer 10a-10d,
The space in the grounded metal container 1 is arranged so as to be airtightly separated from each other for maintenance and separation.
That is, the space inside the grounded metal container 1 is
It is divided into a plurality of gas compartments by 0a to 10d, and the insulating gas 9 is enclosed in each gas compartment. In addition, 1 in the figure
Reference numeral 1 is a gas cylinder, and each gas compartment in the grounded metal container 1 is filled with gas from the gas cylinder 11 via a gas cubicle 12 and a valve 13. Of these, the gas cubicle 12 also has a function of detecting the pressure of each gas compartment.

Further, in FIG. 9, the main circuit is connected to a transformer 19 via a disconnector 5, a circuit breaker 7 and a bushing 14. Although FIG. 9 shows a one-line power receiving main circuit, power is supplied from the power receiving main circuit (not shown) on the right side of the power receiving main circuit to the transformer 19 via the disconnector 5. In some cases.

Further, reference numeral 15 in the drawing denotes a switchboard, and switches (switch disconnector 5, circuit breaker 7,
It has a function of giving an urging signal to each operation device 17 of the earthing switch 4) to control switching of the main circuits of the switches and interruption operation. Further, reference numeral 18 in the drawing denotes a compressor facility that serves as a drive source for the switches. A predetermined pressure (for example, generally 15 kg / cm ² ) obtained by the compressor equipment 18 is applied to each operation device 17 via the operation cubicle 16.
And the switches are operated.

The gas-insulated equipment having the above structure has the following advantages. That is, due to the excellent characteristics of the insulating gas 9, the storage device can be downsized, and the entire device can be downsized. In other words, KV
The occupied volume per A is reduced, and the effective use of the installation site becomes possible. At the same time, using the gas busbar, 2 to 3 steps
Since a stacked structure of stages can be achieved and block stacking can be achieved, a large volume can be achieved with a small area.

Further, since the grounded metal container 1 is grounded, there is no fear of electric shock even if the grounded metal container 1 is approached during charging. In addition, since the electricity applying section is housed in the grounded metal container 1, it is not directly exposed to salt damage, wind damage and the like. Therefore, there is no fear of deterioration due to external factors, and environmental resistance is high. Moreover, since various switches are subjected to arc treatment in SF ₆ gas having a high arc extinguishing ability, the breaking capacity per main contact can be significantly improved.

However, while the gas-insulated equipment as shown in FIG. 9 has the above advantages, it also has the following drawbacks. That is, as a result of downsizing the gas-insulated equipment as a whole, the size of the rotating work or the reassembling work is limited to a small size during maintenance and inspection of the storage equipment. Therefore, it takes a long time to perform maintenance / inspection work on the storage equipment, and work efficiency is significantly reduced.

Further, since the insulating gas 9 enclosed in the grounded metal container 1 is expensive, the manufacturing technique for preventing gas leakage to the outside is high-grade and the electric field strength is large due to the good insulating property. Since the pressure drop reacts extremely sensitively to insulation tolerance, it is necessary to complete an emergency repair system for gas leaks. Furthermore, in replacement work due to the exhaustion of the main contacts of various switchgear, it takes a lot of time to recover and refill the insulating gas, which makes the gas insulation device downtime longer and hinders stable power supply. It also has the drawback of coming.

As explained above, the gas-insulated equipment includes
Not only the advantages, but also some drawbacks. However, the performance advantages of gas-insulated equipment are sufficient even if the drawbacks are compensated for. Therefore, gas-insulated equipment has been remarkably popularized in recent years, and the number of installation locations has increased, enabling mass production. As a result, the gas-insulated equipment is required to have higher reliability, and the maintenance of the equipment, preparation for the emergency repair system, and the variation in quality have become problems that cannot be ignored.

As a countermeasure against the above-mentioned problems in gas-insulated equipment, it has been earnestly desired to establish a preventive maintenance system capable of confirming the reliability that the operating condition is normal and enabling early detection and monitoring when an abnormality occurs. There is. It is expected that the introduction of this preventive maintenance system will prevent accidents of gas-insulated equipment in order to provide stable power supply and at the same time minimize economic loss due to the accident.

As an example of such a preventive maintenance system, a gas pressure monitoring device has been conventionally proposed. The gas pressure monitoring device is a device that uses a gas pressure sensor to monitor fluctuations in gas pressure in the gas compartment of the gas insulating device.

According to such a gas pressure monitor, a gas leak, an internal ground fault, which cannot be visually detected,
Since it is possible to quickly find defects in the grounded metal container such as defective internal contact when they occur, it is possible to prevent accidents. Moreover, since the gas pressures of all the gas compartments can be monitored by this device, there is also an advantage that the inspection work for inspection is not necessary and the labor can be saved.

The structure of the gas pressure sensor used in the above gas pressure monitoring device will be described below. That is, as shown in FIG.
1 is configured in a case 21, a gas pipe 70 filled with gas is drawn out from the inside of the case 21, and its tip (not shown) is connected to a ground metal container of a gas-insulated device. It is connected. In addition, the partition membrane 2 having elasticity is provided at the base end portion inside the case 21 of the gas pipe 70.
3, a liquid chamber 24 is provided, and the partition membrane 2
The gas in the gas pipe 70 and the liquid such as oil in the liquid chamber 24 are separated by 3.

A diaphragm 25 made of stainless steel or the like is disposed on the opposite side of the partition film 23 in the liquid chamber 24, and a strain of the diaphragm 25 on the outer surface of the liquid chamber 24 of the diagram 25 changes in resistance. A piezoresistive element 26 for converting into A resistance element 27 is connected to the piezoresistive element 26, and the piezoresistive element 26 and the resistance element 27 constitute a bridge circuit.

Further, an electronic circuit 28 for amplifying the signal and an output signal line 30 are sequentially connected to the bridge circuit, and the output signal line 30 is drawn out of the case 21 and is not shown in the figure. It is connected to the.
Further, in the figure, 29 is a power supply circuit for supplying power to the electronic circuit 28, and 31 is a power supply line.

The gas pressure sensor 41 constructed as described above
In the above, when the pressure of the insulating gas in the grounded metal container of the gas insulating device changes and the gas pressure in the gas pipe 70 changes, the pressure fluctuations are caused by the partition membrane 23, the liquid in the liquid chamber 24 and the diaphragm 25. Is transmitted to the piezoresistive element 26 via. Then, it is output from the piezoresistive element 26 to the electronic circuit 28 via the resistive element 27, and the electronic circuit 28 transmits the pressure change as an electric output signal to the monitoring means. In this way, when the pressure of the insulating gas in the grounded metal container of the gas insulation device changes, the output signal of the gas pressure sensor 41 changes.

By the way, it can be presumed that the cause of the change in pressure of the insulating gas in the grounded metal container of the gas insulated device is as follows.

(1) Change in gas temperature due to insolation, etc. (2) Change in heat generation amount due to fluctuation in energizing current (3) Occurrence of gas leak (4) Change in heat generation amount due to abnormal energization such as poor contact (5) Occurrence of internal ground fault, etc. Here, the causes (1) and (2) are fluctuations in gas pressure that occur when there is no problem in the gas-insulated equipment itself (healthy state), and Gas pressure fluctuates (3)
Needless to say, it should be distinguished from the causes shown in (5) to (5). In order to make this distinction, conventionally, for each gas compartment, a method of converting the gas pressure into a pressure at a predetermined temperature (for example, 20 ° C.) (temperature conversion) is used, and the internal gas of each gas compartment is It was monitoring changes in gas pressure. In this method, the normal gas compartment and the gas compartment in which an abnormality has occurred due to the causes described in (3) to (5) above are distinguished by comparing with other gas compartments.

As described above, in order to determine the cause of the abnormality by performing the temperature conversion on the gas pressure of each gas section, it is necessary to measure the gas temperature together with the gas pressure. In this case, since the gas insulation device has a plurality of gas compartments, it is considered that the optimal method is to measure the gas temperature for each gas compartment.

However, in this method, since the gas temperature detecting means is attached to each gas section, its attaching property and maintainability become problems. Therefore, in the conventional gas pressure monitoring device for gas insulation equipment, a temperature detecting unit for measuring the outside air temperature (the temperature outside the grounded metal container) is
It was provided at one place or a plurality of places, and this measured value was used as the conversion gas temperature of all gas sections.

The temperature detecting section 45 as described above is connected to the monitoring means together with the gas pressure sensor 41. As shown in FIG. 11, the monitoring means includes a first insulation converter 42a for converting output signals from the gas pressure sensors 41a to 41n into pressure signals, and an output signal from the temperature detecting unit 45 for temperature signals. A second isolation converter 42b for converting into Then, the first and second isolation converters 42a,
42b are connected to the same processing unit 43. The processing unit 43 is configured to convert the measured value of gas pressure into gas pressure at a predetermined temperature from the pressure signal and the temperature signal. Further, the processing unit 43 includes a display unit 44.
Are connected, and the result of the processing unit 43 is displayed.

As described above, the gas pressure monitoring device comprising the gas pressure sensor 41, the temperature detecting section 45 and the monitoring means is provided, and the fluctuation of the gas pressure in each gas compartment of the gas insulating equipment is monitored to thereby detect the gas pressure. The cause of the change had been determined.

[0026]

However, the conventional gas pressure monitoring apparatus for gas insulation equipment having the above-mentioned structure has the following problems. That is, a temperature difference occurs in each gas compartment depending on the conditions such as the installation location of the gas insulation device. On the other hand, the temperature detection unit is provided at one or more positions outside the grounded metal container, and a gas section in which the difference between the measured value and the actual gas temperature is greatly deviated is also generated. Further, when the temperature detecting unit that detects the outside air temperature is affected by solar radiation or the like, a temperature difference is generated between the actual gas temperature and the actual temperature. As described above, the outside air temperature cannot be said to be appropriate as the conversion gas temperature, and it is difficult to accurately determine the cause of the gas pressure fluctuation in the gas compartment by the conversion pressure thus obtained.

The present invention has been proposed in order to solve the above-mentioned drawbacks of the prior art, and its object is to accurately convert the gas pressure of each gas compartment into a temperature.
It is an object of the present invention to provide a gas pressure monitoring device for a gas insulation device that can accurately and quickly determine the cause of gas pressure fluctuations.

[0028]

According to a first aspect of the present invention, a plurality of gas compartments are provided in a gas-insulated device in which a high-voltage conductor is housed in a grounded metal container in which an insulating gas is sealed. A gas pressure sensor that measures the gas pressure and outputs a gas pressure signal is arranged for each section, and based on the gas pressure signal from the gas pressure sensor, the gas pressure for each gas section of the gas insulation device. In the gas pressure monitoring device for gas insulation equipment for monitoring the gas pressure, a gas temperature detecting means for measuring the gas temperature in each gas compartment and outputting a gas temperature signal is provided for each of the gas compartments. A processing unit for converting a gas pressure signal from the sensor into a pressure of a predetermined temperature based on the gas temperature signal is provided.

According to a second aspect of the present invention, a plurality of gas compartments are provided in a gas insulation device in which a high-voltage conductor is housed in a grounded metal container in which an insulating gas is sealed. A gas pressure sensor that measures a pressure and outputs a gas pressure signal is arranged, and a gas insulation device that monitors the gas pressure for each gas section of the gas insulation device based on the gas pressure signal from the gas pressure sensor. In the gas pressure monitoring device, the gas temperature detecting means for measuring the gas temperature in the gas compartment and outputting a gas temperature signal is provided in at least one of the gas compartments, and the gas from the gas pressure sensor is used. A processing unit for converting the pressure signal into a pressure of a predetermined temperature based on the gas temperature signal is provided.

According to a third aspect of the present invention, in the gas pressure monitoring device of the gas insulation device according to the first or second aspect, the processing unit is configured so that the gas pressure signals of the respective gas sections are of the same gas section. It is characterized in that it is configured to convert the pressure to a predetermined temperature based on the gas temperature signal.

According to a fourth aspect of the present invention, in the gas pressure monitoring device for a gas insulated device according to the first aspect, the gas pressure sensor is operated based on a gas temperature signal which is an average value of gas temperatures of all gas sections. The gas pressure signal of is converted into a pressure of a predetermined temperature.

According to a fifth aspect of the present invention, in the gas pressure monitoring apparatus for gas insulating equipment according to the first aspect, a gas temperature signal which is an average value of gas temperatures obtained for each gas section group consisting of a plurality of gas sections. Based on the above, the gas pressure signal from the gas pressure sensor is converted into a pressure of a predetermined temperature.

According to a sixth aspect of the present invention, in the gas pressure monitoring device for gas insulating equipment according to any one of the first to fifth aspects, the gas temperature detecting means is the same as the gas pressure sensor. It is characterized by being provided in the case.

[0034]

According to the first and second aspects of the invention, the gas temperature detecting means is provided for each gas section or in at least one of the gas sections, and the temperature of the gas is directly measured. Therefore, the gas pressure in the gas compartment is
It is converted into a pressure (converted pressure) of a predetermined temperature based on the gas temperature in each gas compartment. In this case, the gas temperature detecting means is not directly affected by solar radiation or the like and an accurate measured value of the gas temperature is obtained, so that an accurate converted pressure is calculated.

According to the third aspect of the present invention, the gas pressure in each gas compartment can be converted into the converted pressure by the gas temperature signal of the same gas compartment, so that the gas pressure in each gas compartment can be highly reliable. Can be monitored.

According to the fourth aspect of the present invention, as the gas temperature signal, the signal composed of the average value of the gas temperatures of all the gas sections is used. As a result, the load of the converted pressure calculating means is reduced. Therefore, the device can be downsized.

According to the fifth aspect of the invention, as the gas temperature signal, the average value of the gas temperature of the gas section group or the gas of the specific gas section of the gas section group is provided for each gas section group consisting of a plurality of gas sections. As a result of configuring to use a signal consisting of temperature, it is possible to obtain a gas pressure monitoring device suitable for gas-insulated equipment such as large-scale substations where the gas temperature is different in gas compartments at a distance. It is possible to reduce the load on the calculating means and calculate a more accurate converted pressure.

According to the sixth aspect of the present invention, by providing the gas temperature detecting means in the same case as the gas pressure sensor, the gas temperature detecting means can be easily installed and the gas pressure and the gas temperature can be simultaneously measured. Can be measured.

[0039]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the gas pressure monitoring device for gas insulation equipment of the present invention will be specifically described below with reference to the drawings.
1 is a configuration diagram showing an embodiment in which the gas pressure monitoring device according to the present invention is applied to a gas insulation device, and FIG. 2 is a configuration diagram showing an example of a gas pressure sensor used in the gas pressure monitoring device of this embodiment. 3, FIG. 3 is a block diagram showing the configuration of the gas pressure monitoring device of the present embodiment, FIG. 4 is a graph showing gas pressure fluctuations during normal operation, FIG. 5 is a graph showing gas pressure fluctuations during gas leak, and FIG. It is a graph which shows the gas pressure fluctuation at the time of a failure occurrence. Further, the same members as those of the conventional type shown in FIGS. 9 to 11 are designated by the same reference numerals, and the description thereof will be omitted.

In this embodiment, as shown in FIG.
The main busbar portion of the gas-insulated equipment supports the grounding metal container 1, the busbar 8 housed in the grounding metal container 1, the insulating gas 9 such as SF ₆ gas sealed in the grounding metal container 1, and the busbar 8. It is composed of an insulating spacer 10 for Then, the inside of the grounded metal container 1 is partitioned by the insulating spacer 10 to configure each of the gas partitions S1, S2, .... Further, each of these gas sections S1, S2, ...
A storage box 72 is disposed near each of the storage boxes 72, and a gas pressure sensor 73 is disposed in the storage box 72. The gas section S1 and the gas pressure sensor 73 are connected via the gas pipe 70 and the gas valve 71. In addition,
In FIG. 1, only the gas pressure sensor 73 provided in the gas section S1 is shown.

The gas pressure sensor 73 has a structure as shown in FIG. That is, the gas pipe 70 filled with gas is drawn out from the inside of the case 21, and the liquid chamber 24 is arranged at the base end portion of the gas pipe 70 inside the case 21 via the partition film 23. Was set up,
The partition film 23 separates the gas in the gas pipe 70 from the liquid such as oil in the liquid chamber 24. A diaphragm 25 is arranged on the opposite side of the partition film 23 in the liquid chamber 24, and a bridge circuit including a piezoresistive element 26 and a resistive element 27 is connected to the outer surface of the liquid chamber 24 of the diaphragm 25. . Then, the electronic circuit 28 and the output signal line 30 are sequentially connected to this bridge circuit, and are connected to a monitoring means (not shown).

Further, the partition film 23 is provided with a gas temperature detecting section 32 as a gas temperature detecting means in the gas pipe 70. The gas temperature detection unit 32 is connected to the electronic circuit 28 that outputs the gas temperature together with the gas pressure as an electric signal.

Further, the gas pressure sensor 7 having such a configuration is used.
As shown in FIG. 3, an upper processing system including an insulation converter 74, a processing unit 75, a display unit 76, and the like is connected to 3 as a monitoring unit. Here, the isolation converter 7
4 is configured to convert the output signals of the gas pressure and the gas temperature from each gas pressure sensor 73 into a pressure signal and a temperature signal and send them to the processing unit 75. Further, the processing unit 75 is configured to convert the gas pressure (converted pressure) at a preset predetermined temperature into a temperature based on the pressure signal and the temperature signal of each gas section sent from the insulation converter 74. ing. Further, a judgment reference value is set in advance in the processing unit 75, and it is configured to compare this value with the converted pressure of each gas section.

In a normal state where there is no problem in the gas insulation device itself, the gas pressure P ₀ measured by the gas pressure sensor 73 and the converted gas pressure P ₁ show waveforms as shown in FIG. That is, as shown in FIG. 4, the converted gas pressure P ₁ shows a constant value, and this value is input to the processing unit 75 as a determination reference value. In such a monitoring means, the measured gas pressure, measured gas temperature, converted pressure, gas pressure increase value, comparison result, etc., which are input to the processing unit 75 and processed, are displayed on the display unit 76 for each gas section. Is configured to be displayed by.

The operation of the gas pressure monitoring device for the gas insulated device of this embodiment having the above-mentioned structure will be described.
First, when an internal failure occurs in the gas section S1 shown in FIG. 1, the gas pressure in this gas section S1 is
When it changes as shown in FIG. 5, the gas pressure inside the gas pipe 70 also changes at the same time. As a result, the change in gas pressure is transmitted at the end of the gas pipe 70 of the gas pressure sensor 73. Then, this pressure change is caused by the partition film 23 and the liquid chamber 24.
It is transmitted to the piezoresistive element 26 via the liquid inside and the diaphragm 25, and the
Is output to the electronic circuit 28 via. On the other hand, the gas temperature detector 32 detects the gas temperature inside the gas compartment and outputs it to the electronic circuit 28. As a result, the electronic circuit 2
From 8, the gas pressure and the gas temperature are transmitted as output signals to the monitoring means via the output signal line 30.

Subsequently, in the monitoring means, the output signals of the gas pressure and the gas temperature are simultaneously converted into the gas pressure signal and the gas temperature signal by the insulation converter 74, which is the processing unit 75.
Sent to In the processing unit 75, the gas pressure signal is converted into a pressure (converted pressure) of a predetermined temperature from each gas temperature signal for each gas section. Even if the measured gas pressure changes, if the converted pressure does not change compared to the determination reference value (when the graph is the same as in FIG. 4), fluctuations in the gas pressure may be due to solar radiation or the like. This is caused by a change in the gas temperature due to the change in the gas temperature or a change in the amount of heat generated due to a change in the energizing current.

On the other hand, when the measured gas pressure fluctuates and the converted pressure also fluctuates with respect to the judgment reference value, a change in the amount of heat generated due to a gas leak, a contact failure, etc. It is determined that the gas pressure in the gas compartment has changed due to the occurrence of a junction or the like.

Particularly, when a gas leak occurs, the amount of gas decreases with the lapse of time, so the gas pressure also decreases in proportion to this. In this regard, the relationship between the gas pressure P ₀ and the converted gas pressure P ₁ has a waveform as shown in FIG. 5, and in the case of such a waveform, the processing unit 75 determines that a gas leak has occurred. Further, when the gas pressure P ₀ changes as shown in FIG. 6, it can be determined that contact failure or internal ground fault has occurred. Then, the determination by the processing unit 75 is displayed on the display unit 76.

As described above, in this embodiment, the gas pressure and the gas temperature of each gas compartment can be measured and the converted pressure can be obtained, so that the fluctuation of the gas pressure can be accurately calculated for each gas compartment. Can be monitored. In particular, by comparing the converted pressure and the determination reference value, the pressure fluctuation can be easily monitored. When there is a change, the cause of the change can be quickly determined. Moreover, since the gas temperature directly measures the temperature of the gas, it is possible to calculate an accurate converted pressure without causing a large temperature difference from the gas temperature due to the influence of solar radiation etc. unlike the outside air temperature of the conventional technology. it can.

Further, in this embodiment, since the gas pressure and the gas temperature of each gas compartment are simultaneously measured and processed in the same processing section, there is no difference in measurement time between the gas pressure and the gas temperature, and the solar radiation is maintained. Even if there is an influence such as the above, an accurate converted pressure can be calculated. Then, since the gas pressure is converted for each gas section by the gas temperature of each gas section, the converted pressure can be accurately calculated even if there is a temperature difference in each gas section.

Moreover, in this embodiment, since the gas temperature detecting unit for measuring the gas temperature is provided in the gas pressure sensor for measuring the gas pressure and is simultaneously output to the same insulation converter, It is not necessary to provide a gas temperature detecting means or an insulation converter therefor separately from the pressure sensor. Therefore, the gas temperature detection unit can be easily installed and can be downsized, and the gas pressure monitoring device with more excellent functions can be provided.

Further, since the gas pressure increase value due to an internal failure can be detected accurately and quickly, the failure point locating function can also be provided.

The present invention is not limited to the above-mentioned embodiments, and the specific configurations of the gas pressure sensor and the monitoring means can be freely selected. That is, the monitoring means is not limited to, for example, a configuration in which the insulation converter converts the output signal of the gas pressure and the output signal of the gas temperature by the same insulation converter, and the first insulation for gas pressure signal conversion is used. The converter and the second isolation converter for gas temperature signal conversion can also be provided separately.

Further, as shown in FIG. 7, the insulation converter is not provided, and the output signals of the gas pressure and the gas temperature from the gas pressure sensors 73a to 73n are directly sent to the processing section 75. You can also In this case, in the processing unit 75, the output signals of the gas pressure and the gas temperature are converted into the pressure signal and the temperature signal, and the converted pressure is obtained from this, or the converted pressure is directly obtained from the output signal of the gas pressure and the gas temperature. The configuration can be appropriately changed such as asking.

Further, in the above embodiment, the gas temperature detecting means for measuring the gas temperature is provided in the gas pressure sensor 73 as the gas temperature detecting section 32, but it is not limited to this, and the gas temperature is directly measured. If so, the gas temperature detecting means can be directly provided in each gas compartment, or can be appropriately changed, such as being provided in a gas pipe connecting each gas compartment and the gas pressure sensor.

Further, in the above-mentioned embodiment, the case where the present invention is applied to the main bus portion of the gas insulation device has been described, but the present invention can be similarly applied to various gas insulation devices and is similarly excellent. It is possible to obtain the same effect.

In the above embodiment, the processing unit 75 of the monitoring means calculates the converted pressure of each gas compartment based on the gas temperature of each gas compartment. However, this can be changed as follows. Is. That is, since the gas temperature detecting means is arranged to directly measure the temperature of the gas,
The gas temperature detecting means is not directly affected by solar radiation or the like.
Therefore, it is possible to obtain the average value of the gas temperature of all the gas sections once and convert the gas pressure of each gas section by this value.

It is also possible to obtain a group average value of gas temperatures for each gas section group consisting of a plurality of gas sections and convert the gas pressure of each gas section of the group by this group average value. . Further, in the gas section group, the gas temperature of the representative gas section may be measured, and this value may be used in each gas section of the gas section group. In this case, the gas temperature should be measured periodically for all gas compartments in the group, and if there is a gas compartment that is significantly different from other gas compartments, monitor it and display it on the display. It can also be configured.

With this configuration, the gas pressure conversion processing operation is simplified and the load is reduced, so that a processing unit with a small processing capacity can be used, and the overall size of the gas pressure monitoring device can be reduced. Can be realized. In particular, in gas-insulated equipment such as large-scale substations, the gas temperature in different gas compartments may be different.In such a case, by using the group average value as the gas temperature, The load can be reduced and the converted pressure can be calculated more accurately. Therefore, it is possible to provide a small and excellent gas pressure monitoring device for a gas insulation device.

Further, in the present invention, the number of monitoring means is not limited to one, and a plurality of monitoring means may be provided. For example, in a gas-insulated device such as a large-scale substation, a gas section may be set as a monitoring section in plural units and a monitoring unit may be provided for each. In this case, an insulation converter is provided for each monitoring section and connected to one processing unit / display section, or an insulation converter and a processing section are provided for each monitoring section, and one display section is connected to this. In addition, it is also possible to provide an insulation converter, a processing unit, and a display unit for each monitoring section. Also,
As shown in FIG. 8, it is possible to enhance the function of locating the failure point by providing the gas pressure sensor in duplicate.

[0061]

As described above, according to the present invention, since the gas temperature in the gas compartment is directly measured, the gas pressure can be accurately converted into the pressure of the predetermined temperature by this temperature. Allows you to reliably monitor changes in gas pressure,
It is possible to provide a gas pressure monitoring device for a gas insulation device that accurately and easily determines the cause.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment in which a gas pressure monitoring device according to the present invention is applied to a gas insulation device.

FIG. 2 is a configuration diagram showing an example of a gas pressure sensor used in the gas pressure monitoring device shown in FIG.

FIG. 3 is a block diagram showing the configuration of a gas pressure monitoring device.

FIG. 4 is a graph showing gas pressure fluctuations under normal conditions

FIG. 5 is a graph showing gas pressure fluctuation when a gas leak occurs.

FIG. 6 is a graph showing gas pressure fluctuation when an internal failure occurs.

FIG. 7 is a block diagram showing another embodiment of the present invention.

FIG. 8 is a configuration diagram showing an example of a dual gas pressure sensor.

FIG. 9 is a configuration diagram showing an example of a typical gas insulation device.

FIG. 10 is a configuration diagram showing an example of a conventional gas pressure sensor.

FIG. 11 is a block diagram showing the configuration of a conventional gas pressure monitoring device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Ground metal container 8 ... Busbar 9 ... Insulating gas 10a-10d ... Insulating spacer 21 ... Case 23 ... Partition film 24 ... Liquid chamber 25 ... Diaphragm 26 ... Piezoresistive element 27 ... Resistor element 28 ... Electronic circuit 29 ... Power supply circuit 30 Output signal line 31 Power supply line 32 Gas temperature detection unit 41, 73 Gas pressure sensor 42a First insulation converter 42b Second insulation converter 43, 75 Processing unit 45 Temperature detection unit 44, 76 ... Display unit 70 ... Gas pipe 74 ... Insulation converter

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Masayuki Akasaki 2-1, Ukishimacho, Kawasaki-ku, Kawasaki-shi, Kanagawa Stock company Toshiba Hamakawasaki factory

Claims (6)

[Claims] 1. A plurality of gas compartments are provided in a gas-insulated device in which a high-voltage conductor is housed in a grounded metal container in which an insulating gas is sealed, and the gas pressure is measured for each of the gas compartments. A gas pressure sensor that outputs a signal is arranged,
In a gas pressure monitoring device for a gas insulation device, which monitors the gas pressure for each gas section of the gas insulation device based on a gas pressure signal from the gas pressure sensor, A gas temperature detecting means for measuring the gas temperature of the gas temperature and outputting a gas temperature signal is provided, and a processing unit for converting the gas pressure signal from the gas pressure sensor into a pressure of a predetermined temperature based on the gas temperature signal. A gas pressure monitoring device for a gas insulation device, which is provided. 2. A plurality of gas compartments are provided in a gas insulating device in which a high-voltage conductor is housed in a grounded metal container in which an insulating gas is sealed, and the gas pressure is measured for each gas compartment. A gas pressure sensor that outputs a signal is arranged,
A gas pressure monitoring device for a gas insulation device, which monitors the gas pressure for each gas section of the gas insulation device based on a gas pressure signal from the gas pressure sensor, wherein the gas is provided in at least one of the gas sections. Gas temperature detecting means for measuring a gas temperature in the compartment and outputting a gas temperature signal is provided, and a process of converting a gas pressure signal from the gas pressure sensor into a pressure of a predetermined temperature based on the gas temperature signal. A gas pressure monitoring device for a gas insulation device, which is provided with a section. 3. The processing unit is configured to convert a gas pressure signal of each gas compartment into a pressure of a predetermined temperature based on a gas temperature signal of the same gas compartment. The gas pressure monitoring device for gas insulating equipment according to claim 1 or 2. 4. The gas pressure signal from the gas pressure sensor is converted into a pressure of a predetermined temperature based on a gas temperature signal which is an average value of gas temperatures of all gas sections. Gas pressure monitoring equipment for gas insulation equipment. 5. A gas pressure signal from the gas pressure sensor is converted into a pressure of a predetermined temperature on the basis of a gas temperature signal which is an average value of gas temperatures obtained for each gas partition group including a plurality of gas partitions. The gas pressure monitoring device for gas insulating equipment according to claim 1. 6. The gas of the gas-insulated equipment according to claim 1, wherein the gas temperature detecting means is provided in the same case as the gas pressure sensor. Pressure monitoring device.