FR2580397A1 - Volumetric detector of leak out of or into the enclosure of a vessel - Google Patents

Abstract

The detector comprises a channel 7 for injecting a gas into the vessel 1 and for creating therein a detection pressure, a dip tube 9 whose lower end dips into the liquid 2 and whose upper end emerges in a first tank 12 which is itself connected by a transparent level-observation tube 13 to a second tank 14, the volume ratio between, on the one hand, the dip tube 9 and the first tank 12, on the other hand, the observation tube 13 and the second tank 14 being such that at the detection pressure, the level of liquid rises in the said assembly until it partially fills the observation tube 13.

Description

 The subject of the present invention is a volumetric leak detector outside or towards the enclosure of a tank having an access capable of being hermetically sealed by shutter means, said detector comprising a pipe adapted to inject a gas into said tank through shutter means to create a detection pressure and an assembly for observing variations in the detection pressure in the tank.

 A detector of this type is described in French patent application No. 2,535,692 of the applicant.

 In the case of this known device, the pipe adapted to inject a gas into the tank and the assembly making it possible to observe the variations in the detection pressure thus created are adapted one after the other on a valve 6 fitted to a pipe 7 which passes through the shutter means. Variations in detection pressure are observed using a conventional pressure gauge.

 The known device has a sensitivity which is acceptable when the leak affecting the tank is located above the level of the liquid which it contains, since a diffusion out of the tank of the compressed gas injected for the control operation is of no importance. convenient ; on the other hand, this sensitivity is insufficient and leads to consequence (pollution) when the leak affecting the tank is located below the level of the liquid because, under the pressure of the injected gas, it is a non-negligible quantity of fuel oil or other liquid which will diffuse outside the tank, before we can detect the leak.

 The object of the present invention is to remedy this drawback by proposing a sensitive, mobile detector, adaptable to any type of tank, especially in a pit or buried, inexpensive and capable of being used whatever the volume of the tank and its filling rate.

 The invention also aims to provide a detector for visual control, more appreciated by operators.

 These various aims are achieved in that the invention proposes a detector of the aforementioned type in which the assembly making it possible to observe the variations in the detection pressure in the tank is constituted by a dip tube passing through the shutter means, the lower end of said tube immersed in the liquid, while its upper end opens into a first reservoir, itself connected by a transparent level observation tube to a second reservoir, said assembly being open only at the level of the the lower end of the dip tube and the volume ratio between, on the one hand, the dip tube and the first tank, on the other hand, the observation tube and the second tank being such that at the detection pressure, the level of the liquid rises in said assembly until it partially fills the observation tube.

The operating principle of the detector according to the invention is simple
At normal atmospheric pressure, the assembly is mounted, in a leaktight manner, through closure means which close the access to the tank, so that the free end of the dip tube plunges into the liquid contained in the tank. At this stage, the liquid rises to a small height in the dip tube, the rest of the volume of the assembly being filled with air.

 When the tank is pressurized by the pipe provided for this purpose, the liquid rises in the dip tube until it completely fills the first reservoir and partially the observation tube. After a few minutes, necessary for temperature and pressure stabilization, the level of the liquid stabilizes in the observation tube and this level is noted.

If there is a leak, the level will vary - either lowering if there is liquid leakage or
of air from the tank to the outside, - either by rising if there is fluid entry from
outside (eg water infiltration).

 As indicated above, the volume ratio between the various components of the assembly making it possible to observe the variations in the detection pressure in the tank must be such that at the detection pressure, the level of the liquid is visible through from the observation tube.

Thus, if we consider that the volume V occupied by the air as a whole at atmospheric pressure, namely 1.013 bar, is 1 and if we apply a detection pressure exceeding P1 the atmospheric pressure, the pressure of the air contained in the assembly will become
P '= 1.013 + P1.

By applying Mariotte's law PV = the new volume under pressure P 'occupied by air V' will be
1.013 1.013 + P1
This volume V ′ must correspond to the volume of the second reservoir and to part of the observation tube.

 Advantageously, the second reservoir is provided with a thermometer and / or a manometer for observing the stabilization of the level of the liquid in the observation tube after placing the tank under the detection pressure.

 To facilitate the use of the detector according to the invention, the observation tube can be provided with a movable mark adapted to be placed opposite the level of the liquid in the observation tube.

 In a preferred embodiment of the invention, the detector further comprises a leak simulator formed by a dip tube hermetically passing through the closure means, the lower end of said tube immersed in the liquid and the upper end being closed. by an openable steam trap.

 This leak simulator is used to check that the system is working properly. It also allows quantitative assessment of leaks per unit of time under a given pressure.

The invention is described below with reference to the accompanying drawings, in which - Figure 1 schematically shows a form of execution
tion of the detector according to the invention mounted on a tank, and - Figures 2a to 2e show schematically different
your variants of the assembly allowing
observe variations in detection pressure in
tank.

 If we refer to Figure 1, we see a tank 1 partially filled with a liquid 2, for example fuel oil.

This tank 1 is buried in the ground 3. The manhole 4 of the tank is hermetically closed by shutter means 5 which can be designed, for example, according to the teaching of the aforementioned French patent application No. 2,535,692 . These shutter means 5 are hermetically traversed, from left to right in the figure, by a calibrated safety valve 6, a pipe 7 joined via a bleeder 8 to a source of compressed air not shown, a dip tube 9 belonging to a set which will be described in detail below, and a leakage simulator 10 opening to the outside via a trap 8. The pipe 7 and the leakage simulator 10 are each equipped with a pressure gauge 11.The free end of the dip tube 9 plunges into the liquid 2, while its opposite end opens into a first reservoir 12 joined by a transparent observation tube 13 to a second reservoir 14. There is a mark on the transparent observation tube 13 15 movable may be brought opposite the liquid level in said tube.

 The reservoir 14 is provided with a pressure gauge 11, a barometer 16 and a thermometer 17. Connectors 18 make it possible to lengthen or shorten, as required, the dip tube 9 and the leak simulator 10.

The device works as follows
When the assembly 9, 12, 13, 14 and its accessories are mounted on the shutter means 5, at normal atmospheric pressure, a little liquid rises in the tube 9 to compensate for the pressure of the depth of liquid (care will be taken to this rise is minimal by choosing, for the dip tube, a correct length).

 The trap 8 of the leak simulator 10 being closed, compressed air is injected into the tank by means of the pipe 7.

 Under the effect of the resulting overpressure, the liquid rises, on the one hand, in the leak simulator and, on the other hand, in the dip tube, the reservoir 12 and part of the observation tube 13. We wait pressure and temperature stabilize by observing barometer 16 and thermometer 17.

 Given the location of the tank (in a pit or buried), stability is obtained in a few minutes.

 The trap 8 of the leakage simulator 10 is then opened to expel the air contained in said simulator and the trap is closed on the arrival of the liquid. It is checked that the pressure loss thus generated in the tank s1 is manifested by a drop in the level of the liquid in the observation tube 13. This operation makes it possible to check that the system is working (for example that it is not obstructed ).

 The liquid level in the observation tube 13 is identified by positioning the level 15 reader. Since the fuel oil is red, this identification is easy.

 All other things being equal (temperature and atmospheric pressure), a time t is expected: the slightest leak in the tank will cause a pressure change which will be revealed by a variation in the level of the liquid in the tube 13.

 Thus, this level will rise in the event of product entry (water infiltration) while it will drop if there is product exit (air or fuel exhaust to the outside).

 We mark the height x corresponding to this change in level and then return to the initial level by adjusting the pressure in the tank (either by lowering the pressure by means of the bleeder 8, or by increasing the pressure by a new admission of compressed air by pipeline 7).

 All other things being equal, during the same time t, the trap 8 of the leakage simulator is opened and a quantity of liquid L is collected, after which the new level y of the liquid in the observation tube 13 is noted.

Two cases arise - If the level of liquid in the tube 13 had dropped, the expression xL / (yx) gives the approximate volume of the leak in a time t, accelerated at the pressure P - if the level of the liquid in the observation tube 13 had mounted, the expression xL / (xy) gives the approximate volume of the liquid inlet in a time t, braked by the pressure
P.

 Leaks in volume being given for a time t under a pressure P, one can transpose if necessary the results in hour flow at normal atmospheric pressure by the formulas of the laws of flow rates.

 It should be noted that, for the limiting case which is that where x = O, we slightly modify P into P 'to avoid being in the case where P could compensate for an entry of liquid at the same pressure. If, with P ', there is still no change in level, the absence of leakage is confirmed.

 When the operation is complete, the trap 8 of the pipe 7 is opened to reduce the pressure of the tank to atmospheric pressure, then the trap 8 of the simulator 10; it follows that- the whole device empties naturally into the tank. There is therefore practically no loss of product.

 As we have seen above, volume ratios must be observed between, on the one hand, the tube 9 and the reservoir 12 and, on the other hand, the tube 13 and the reservoir 14.

 Another precaution resides in the choice of the volume of the reservoir 14 because it determines the reliability of the device by varying the volume of this reservoir 14 relative to the volume of air contained in the tank; reliability is increased at will. However, care must be taken to keep the volume ratios necessary for reading on the observation tube 13 for the construction of the tanks 12 and 14 and the tubes 9 and 13.

 It should be noted that at the pressure gauge 11 of the reservoir 14, the pressure P indicated is lower than the pressure P 'of the tank since P' is equal to P + hwg where h = height of the liquid in the set 9, 12, 13, w = density of the liquid g = acceleration of gravity.

With fuel oil and liquid heights up to 3 meters (depth of a tank) and a height of the assembly 9, 12, 13 (up to the reading level) of approximately 1 meter, h varies between 1 and 4 meters.

 The pressure corresponding to the height of liquid hwg therefore varies between 1000 x 0, 89 x 9.8 x 10 5 = 0.087 bar and 4000 x 0.89 x 9.8 x 10 5 = 0.348 bar.

To have a reading level at a test pressure x in the tank 14, we must therefore raise the pressure in the tank between
x + 0.087 bar and x + O, 348 bar.

 It will therefore be necessary to ensure that the levels of retest are within the standards for retest set by legislative texts.

If we take a re-test pressure of 0.5 bar for fuel oil, we will vary in the
0.5 + 0.087 = 0.587 to 0.5 + 0.348 = 0.848 which is in accordance with said texts, but it will be necessary to choose the volumes of the tanks 12 and 14 in a corresponding manner.

 Figures 2a to 2e show different configurations of the tanks 12 and 14 and the tube 13: the tanks can both be located outside the tank as in Figures 2a and 2b, both are located inside the tank, as in Figure 2d, or be located one outside of the tank, the other inside, as in Figures 2c and 2e, the only important point being that the tube 13 is , him, outside the tank to allow the observation of the liquid level.

 It is understood that the present invention is not limited to the embodiment described and shown. In particular, instead of fuel oil, the liquid could be diesel, water, etc ...; instead of being air, the compressed gas could be nitrogen, etc.

Claims (4)

 1 - Volumetric leak detector outside, or towards, the enclosure of a tank having an access capable of being hermetically closed by shutter means, said detector comprising a pipe adapted to inject a gas into said tank through means shutters for creating a detection pressure therein and an assembly making it possible to observe the variations in the detection pressure in the tank, characterized in that said assembly consists of a dip tube (9) passing through the shutter means (5), l the lower end of said tube (9) immersed in the liquid (2) while its upper end opens into a first reservoir (12), itself connected by a transparent level observation tube (13) to a second reservoir (14 ), said assembly being open only at the lower end of the dip tube (9) and the volume ratio between, on the one hand, the dip tube (9) and the first reservoir (12), d '' other pa rt, the observation tube (13) and the second reservoir (14) being such that at the detection pressure, the liquid level rises in said assembly until partially filling the observation tube (13).  2 - Device according to claim 1, characterized in that the second tank (14) is provided with a thermometer (17) and / or a barometer (16).  3 - Detector according to claim 1 or 2, characterized in that the observation tube (13) is provided with a movable mark (15) adapted to be placed opposite the level of liquid in said tube d 'observation.  4 - Detector according to any of claims 1 to 3, characterized in that it further comprises a leak simulator (10) formed of a dip tube hermetically passing through the shutter means (5), the lower end of said tube (10) immersed in the liquid (2) and the upper end being closed by a trap (8) openable at will.