EP0911846A1 - Method for high precision determination of a leak rate in an encapsulated electrical apparatus - Google Patents

Abstract

A set of parameter values are taken over a period of time allowing correlation to be made between the values providing a more accurate escape index indication.

Description

The invention relates to a method for determining a leak rate. from a series of density values of a contained dielectric gas under pressure in an envelope inside which is arranged an electrical device crossed by an electric current, each density value being calculated by a unit of recording and processing from corresponding pairs of pressure values and temperature delivered simultaneously by a pressure sensor and by a temperature sensor fixed on the envelope from the outside and communicating with the dielectric gas.

A distribution network or generator circuit breaker constitutes an application of such electrical equipment, in which the dielectric gas contained in the envelope is for example sulfur hexafluoride SF ₆ . Present under a pressure of a few bars in a pure state or mixed with another gas such as air or carbon tetrachloride CCl ₄ , SF ₆ is used to extinguish an electric arc which forms in the envelope during l opening of the circuit breaker.

The pressure sensor and the temperature sensor are mounted from the outside on the envelope and communicate with the gas dielectric by a conduit formed in the thickness of the envelope. Each record of measured pressure and temperature simultaneously by these sensors allows to calculate a value of density which is representative of the actual density of the dielectric gas contained in the envelope to the nearest measurement uncertainties.

We know that the temperature measurement simultaneously with that pressure allows, by temperature compensation, overcome a decrease in pressure which is not the result of a loss of mass or leakage of the dielectric gas out of the envelope, but only from a contraction of the dielectric gas under the effect of a decrease in temperature.

With the process which has just been described, it is possible to control mass losses of a few percent per year. However, environmental protection standards can ultimately establish a control at one per mile per year, and in particular for SF ₆ or CCl ₄ .

Temperature compensation reveals itself insufficient to guarantee such precise control, since the measured pressure value is corrected with respect to the value measured from the temperature and not from the actual value of the temperature of the dielectric gas contained in the envelope.

The object of the invention is to improve the measurement accuracy of a leakage rate of a dielectric gas contained in an envelope of a electrical equipment.

To this end, the subject of the invention is a method for determining a leak rate from a series of gas density values dielectric contained under pressure in an envelope inside which is placed an electrical apparatus crossed by a current electric, each density value being calculated by a unit recording and processing from corresponding couples pressure and temperature values delivered simultaneously by a pressure sensor and a temperature sensor fixed on the envelope from the outside and communicating with the dielectric gas, characterized in that each density value is indexed by unit recording and processing according to a current value electric and a value of a climatic parameter of a medium in which is placed the envelope, recorded simultaneously at each corresponding couple of pressure and temperature values, for determine the leak rate from indexed leak rates which are obtained from density values indexed by the same index.

According to the invention, the values of the electric current flowing electrical equipment are recorded to take into account a heat exchange between this equipment and the dielectric gas contained in the envelope. Similarly, the values of the parameter of the environment in which the envelope is placed are recorded to take into account a heat exchange between the medium and the temperature sensor attached to the enclosure.

Any difference between the actual temperature of the dielectric gas and the temperature measured by the sensor attached to the enclosure, due for example to a difference in thermal inertia of the gas and of the temperature mounted in the sensor, remains essentially the same if is generated by a substantially constant electric current and by a substantially constant climatic parameter also.

Recording an electric current value and a value of the climatic parameter simultaneously with each couple corresponding pressure and temperature values allows the recording and processing unit to assign the same index to density values associated with electric current values close to each other and to values of the climatic parameter also close to each other.

From which it follows that an indexed leakage rate, calculated from density values of the same index, depends only in one way negligible the substantially constant gap between the actual temperature of the dielectric gas and the temperature measured by the sensor fixed on the envelope. The measurement accuracy of the indexed leakage is thus improved, as is the determination of the leak rate, obtained by an average indexed leak rate.

Other characteristics and advantages of the invention will appear on reading the description illustrated by the drawings.

Figure 1 is a block diagram including an apparatus electric on which is implemented the method according to the invention.

Figure 2 shows a series of recordings made according to the method of the invention.

Figure 3 shows two plots for calculating an indexed leak rate according to the method of the invention.

An electrical apparatus, for example a circuit breaker, is shown diagrammatically, FIG. 1, in the form of a tank 4 arranged in a cylindrical envelope 1 filled with a dielectric gas 7 such as SF ₆ under a pressure of a few bars. The circuit breaker is connected to two current leads 3 and 5.

A pressure sensor and a temperature sensor are attached on the envelope from the outside. In the example in Figure 1, the pressure sensor 11 is equipped with a temperature sensor internal, and does not require mounting a second temperature.

The pressure sensor communicates with the dielectric gas contained in the envelope by a relatively narrow conduit 9 which contains the temperature probe and a pressure sensor, for example an elastic membrane.

The pressure sensor 11 delivers to a unit recording and processing 13 a couple of pressure values P and temperature T acquired simultaneously. The couples of values are recorded for example every hour during a time period of one year to form an annual series of records. It is also planned to record the couples of pressure and temperature values sporadically during this period of time, for example on each change significant of the measured temperature. Each pair of values is processed by the recording and processing unit 13 to calculate a value of the density of the dielectric gas contained in the envelope in using for example an empirical equation of state known in the literature.

According to the invention, the method provides for simultaneous recording for each pair of pressure and temperature values, a value of the electric current flowing through the electrical equipment, and a value of a climatic parameter of the environment in which is arranged the enclosure.

In the example of FIG. 1, a first measuring device 17 of the type of an ammeter is arranged in bypass on the two current leads 3 and 5 to deliver to the recording unit and processing 13 a value of the intensity I of the electric current.

A second measuring device 15 comprising a thermometer is placed in the ambient medium of the envelope 3 which is generally atmospheric air, for delivering to the recording and processing unit 13 a value of the temperature T _ext of the air.

It is planned to measure with the measuring device 15 other climatic parameters of the ambient environment of envelope 3, such as for example, the solar radiation directed on the envelope, the degree atmospheric humidity, or wind speed, the measure 15 being equipped with sensors corresponding to each of these climatic parameters.

The values of the electric current and the climatic parameter are processed by unit 13 to assign an index to the value of the density calculated from each corresponding pair of values pressure and temperature.

In Figure 2, there is shown a series of n = 10 records acquired by the unit 13, which each include a pair of pressure values P _n and temperature T _n , an electric current value, and a temperature value air.

A value of the electric current, in amperes, is allowed in one of the following four intervals: I1 = [0 - 500], I2 = [500 - 1000], I3 = [1000 - 1500] and I4 = [1500 - 2000]. If the value of the electric current is not in any of these ranges, the record is stored in a memory separate from unit 13.

A value for the outside temperature, in degrees Celsius, is allowed in one of the following three intervals: I5 = [-10 - 0], I6 = [0 - 10] and I7 = [10 - 20]. If the outdoor temperature value is not included in none of these intervals, the record is stored in a memory separate from unit 13.

An index consists of a range of current values electric combined with an interval of climatic parameter values. The four ranges of electric current values and the three outdoor temperature value ranges form per meeting two to two twelve separate indexes C1 to C12.

The four density values determined from records that have the numbers 1, 4, 8 and 10 are associated with four electric current values allowed in the same first interval I1 and at four permissible air temperature values in the same second interval I5. These four densities have the same index C1 defined by the union of the interval I1 and I5.

The six density values determined from records that bear the numbers 2, 3, 5, 6, 7 and 9 are associated with six values of electric current accepted in the same first interval I4 and at six permitted air temperature values in the same second interval I5. These six densities have the same index C10 defined by the meeting of the interval I4 and I5.

The example of figure 2, which includes only one parameter climatic, easily generalized to several parameters climatic conditions.

At the end of the series, or during the series if the number of records already acquired is sufficient, density values having the same index are processed to calculate an indexed leakage rate τ _i .

Figure 3, we have reported density values as a function of the number of the records for the indexes C1 and C10 shown in Figure 2 and symbolized respectively by triangles and squares. These values are organized into two distinct sets which roughly draw two lines. The recording and processing unit 13 performs on each set of density values of the same index, a linear regression and calculates a leakage rate indexed τ ₁ and τ ₁₀ by the slope of each of the two lines.

Note that the two lines are substantially parallel between them and that they are offset in the direction of the axis which carry the density values. This shift is interpreted by two temperature differences between the temperature measured by the sensor and the actual temperature of the dielectric gas substantially constant for each line but different from one line to another. The parallelism of straight lines illustrates that any constant deviation is practically without influence on the indexed leakage rate calculated from values of density with the same index.

As a result, the accuracy of measuring leakage rates indexed and that of the leakage rate τ, obtained by an average rate leakage indexed, is higher as the value intervals of the electric current and the climatic parameter gathered in an index are narrower.

Claims (7)

Method for determining a leakage rate of a dielectric gas (7) under pressure in a casing (1) of an electrical apparatus, consisting in carrying out, over a certain period of time, measurements of the temperature (T) and of the pressure (P) of the gas inside the envelope by means of a temperature sensor and a pressure sensor (11) fixed on the envelope from the outside, to be determined a series of values density of the gas from the corresponding pairs of measured values of pressure and temperature, and determining the leak rate on the basis of this series of density values, characterized in that simultaneously with the measurement of a temperature couple and gas pressure inside the envelope, the current (I) flowing through the apparatus placed inside the envelope and a climatic parameter (T _ext ) of the medium in which the l is placed are measured. 'envelope, to assign to the density value é corresponding to said pair of measured values of temperature and pressure, one index from a set of different indexes (C1, C12), each index corresponding to an interval (I1 to I7) in which the measured value of the current is located and the measured value of the climatic parameter, in that, on the basis of the density values having the same index, a leak rate corresponding to this index is determined, and in that on the basis of the leak rates (τ ₁ to τ ₁₀ ) corresponding respectively to the different indexes, the gas leakage rate in the envelope is determined. The method of claim 1, wherein the climatic parameter is the temperature of the air in which is arranged the envelope. The method of claim 1, wherein the climatic parameter is the solar radiation crossing the air in which is arranged the envelope. The method of claim 1, wherein the climatic parameter is the degree of humidity of the air in which is arranged the envelope. The method of claim 1, wherein the climatic parameter is the wind speed of the air in which is arranged the envelope. The method according to one of claims 1 to 5, in which is determined a leakage rate corresponding to an index in performing linear regression on density values corresponding to this index and in which the rate of gas leakage in the envelope is determined by averaging the leak rates corresponding respectively to the different indexes. The method of claim 6, wherein the determination of the leakage rates corresponding respectively to different indexes and the rate of gas leakage in the envelope is performed by a recording and processing unit (13) connected to said pressure and temperature sensor (11), the unit recording and processing recording in memory so regular or sporadic each couple of measured values of temperature and pressure together with a current value and a climate parameter value.

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