SENSOR FOR DETERMINING A LIQUID LEVEL FOR AN AIRCRAFT TANK, ASSEMBLY OF A TANK AND A SENSOR, METHOD OF USING SUCH A SENSOR

Abstract

The invention relates to a sensor (1) for determining a liquid level (NE) for an aircraft tank (100), the determining sensor (1) comprising a closure device (2) for closing a port (101) of the tank (100) and a measuring device (3), removably mounted on the closure device (2), comprising a liquid line (20) configured to convey liquid from the port (100) of the tank (100), and a member (21) for automatically sealing the liquid line (20) if the measuring device (3) is not mounted on the closure device (2), the measuring device (3) comprising at least one pressure measuring member (30) configured to measure a pressure difference between the liquid pressure (P1) in the liquid line (20) and a reference pressure (P2) in order to deduce the liquid level (NE) thereof.

Claims

1.-10. (canceled)

11. An assembly of an aircraft tank and a sensor for determining a liquid level for an aircraft tank, the sensor comprising: a closure device, mounted in a port of the tank allowing liquid to circulate, and a measuring device, removably mounted on the closure device, the closure device comprising a liquid line configured to conduct liquid from the port of the tank and a member for automatically sealing the liquid line if the measuring device is not mounted on the closure device, the measuring device comprising at least one pressure measuring member configured to measure a pressure difference between, on the one hand, a liquid pressure in the liquid line and, on the other hand, a reference pressure so as to deduce therefrom the liquid level in the tank, and the tank comprising a mouthpiece formed around the port, the mouthpiece comprising at least one opening, in fluidic communication with a gas phase of the tank via a first internal gas line portion formed in a thickness of a wall of the tank, the closure device comprising a second internal gas line portion configured to supply the measuring member with the gas pressure as reference pressure.

12. The assembly according to claim 11, wherein the measuring device comprises an external line opening to the outside of the tank to measure the external pressure as reference pressure.

13. The assembly according to claim 11, wherein the measuring device comprises two pressure measuring members.

14. The assembly according to claim 11, wherein the tank having a minimum liquid height designated as alert height, the port is positioned at a height lower than said alert height.

15. The assembly according to claim 11, wherein the port being a drain port of the tank in which a drain plug is mounted, the sensor is integrated into said drain plug.

16. The assembly according to claim 11, comprising at least one auxiliary pressure sensor configured to measure a liquid pressure at a determined height of the port so as to deduce therefrom a liquid density.

17. An aircraft comprising an assembly according to claim 11.

18. A method of using an assembly of an aircraft sensor and a tank according to claim 11, the closure device of the sensor being mounted in the port of the tank, the sealing member sealing the liquid line, the method comprising steps consisting of: mounting the measuring device on the closing device so as to place the measuring member in fluidic communication with the liquid pressure, the sealing member being inactivated following the mounting, measuring a pressure difference between, on the one hand, the liquid pressure in the liquid line and, on the other hand, a reference pressure so as to deduce therefrom the liquid level in the tank.

19. The method of use according to claim 18, comprising a step of emitting an alarm when the liquid pressure is equal to the reference pressure.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] The invention will be better understood upon reading the following description, given as an example, and referring to the following figures, given as non-limiting examples, wherein identical references are given to similar objects.

[0029] FIG. 1 is a schematic representation of a tank with a differential measuring sensor according to the prior art.

[0030] FIG. 2 is a schematic representation of a tank with a sensor according to a first embodiment of the invention.

[0031] FIG. 3 is a close-up schematic representation of the sensor of FIG. 2.

[0032] FIG. 4 is a schematic representation of a tank with a sensor according to a second embodiment of the invention.

[0033] FIG. 5 is a schematic representation of a tank with a sensor according to a third embodiment of the invention.

[0034] FIG. 6, FIG. 7 and FIG. 8 are schematic representations of the integration of two measuring members in a sensor.

[0035] FIG. 9 is a schematic representation of the use of an auxiliary sensor to determine the liquid density.

[0036] It should be noted that the figures set out the invention in detail in order to implement the invention, said figures may of course be used to better define the invention where applicable.

DETAILED DESCRIPTION

[0037] The invention will be presented for an oil tank of a helicopter, but it goes without saying that the invention applies to other types of tank (fuel, coolant, etc.) and to other types of aircraft (airplane, etc.).

[0038] With reference to FIG. 2, a tank 100 of a helicopter is schematically represented. The tank 100 is represented in the form of a block but this is generally complex with a non-flat bottom. The tank 100 comprises a liquid phase PL, the level of which is variable, and a complementary gas phase PG. The interface between the two phases PL, PG corresponds to the liquid level NL to be determined.

[0039] In this example, the tank 100 has a wall 102 having a thickness making it possible to withstand pressure, generally metallic. The tank 100 has at least one liquid inlet H1 and one liquid outlet H2 in order to supply a liquid circuit, in particular an oil circuit for cooling components of an aircraft turbomachine.

[0040] In this preferred embodiment, the tank 100 comprises a drain port 101 that is positioned at a low point of the tank 100 so as to allow its draining by gravity. Such a drain port 101 is formed during the manufacture of a tank 100 and advantageously does not require any additional machining.

[0041] As illustrated in FIG. 3, the drain port 101 comprises a mouthpiece, preferably cylindrical, to cooperate with a drain plug closing said drain port 101. In this embodiment, a sensor 1 for determining a liquid level NL is integrated into said drain plug so that the latter advantageously fulfills a dual function and limits the bulk.

[0042] Nevertheless, it goes without saying that the sensor 1 could be used independently, in particular, in a fluid circulation port other than the drain port 101.

[0043] Preferably, the sensor 1 is positioned at a height lower than a minimum liquid height designated as alert height HA. Thus, the sensor 1 is always immersed and subjected to the liquid pressure as will be presented hereafter. The drain port 101 has a very low height and complies with this condition. Preferably, the sensor 1 is situated in a position not subject to eddies due to liquid suction and backflow (proximity of the liquid inlet H1 and the liquid outlet H2). The drain port 101 is generally situated in an opposite manner and complies with this condition.

[0044] When starting an aircraft turbomachine, a certain amount of oil is taken to fill the pipes of the turbomachine (gulping phenomenon). Advantageously, the warning height HA takes this phenomenon into account.

Sensor for Determining a Liquid Level

[0045] With reference to FIG. 3, according to a first embodiment, the sensor 1 comprises a closure device 2, configured to be mounted in the drain port 101 and a measuring device 3, removably mounted on the closure device 2. In other words, the measuring device 3 forms a removable accessory that is not necessary to close the tank 100. Due to its removable nature, the maintenance of the measuring device 3 is greatly simplified.

[0046] The closure device 2 comprises a liquid line 20 configured to conduct liquid from the drain port 101 and a member 21 for automatically sealing the liquid line 20 if the measuring device 3 is not mounted on the closure device 2. As will be presented hereafter, the cooperation of the measuring device 3 with the closure device 2 makes it possible to deactivate the automatic sealing member 21 and allows a circulation of liquid allowing the liquid pressure P2 to be measured. The automatic sealing member 21 may be in various forms, in particular a non-return valve.

[0047] Thus, the closure device 2 advantageously fulfills a stopper function by stopping up the drain port 101. The measuring device 3 makes it possible to measure the fluid level NL and may be replaced rapidly in the event of a malfunction. This solution is advantageous given that it is transposable to any existing tank 100. In addition, in the event of maintenance or technological evolution of the measuring device 3, it may be replaced in a practical manner.

[0048] Preferably, the closure device 2 and the measuring device 3 are mounted together mechanically, for example, by screwing, fitting together, by a bayonet system or other. It goes without saying that a magnetic mounting could also be suitable.

[0049] According to one aspect of the invention, to enable draining, a tube is inserted from the outside into the automatic sealing member 21 in order to deactivate it and allow the liquid to flow. Alternatively, with reference to FIG. 3, the closure device 2 could comprise a control lever 22 configured to deactivate the automatic sealing member 21 and to allow emptying of the tank 100.

[0050] According to the invention, the measuring device 3 comprises at least one pressure measuring member 30 configured to measure a pressure difference between, on the one hand, the liquid pressure P1 in the liquid line 20 and, on the other hand, a reference pressure so as to deduce therefrom the liquid level NL in the tank 100. As will be presented hereafter, the reference pressure may be of different nature.

[0051] The measuring device 30 is connected to a calculator 6 of the aircraft in order to provide liquid level information to the aircraft propulsion system or to the pilot.

[0052] Preferably, the pressure measuring member 30 is in the form of an electronic chip configured to determine a pressure difference between the liquid pressure P1 and the reference pressure.

[0053] In this first embodiment, with reference to FIG. 3, the measuring device 3 comprises a single pressure measuring member 30. The measuring device 3 comprises an external line 31, opening to the outside of the tank 100. In other words, the reference pressure is the external pressure Pext of the external medium Mext, i.e. the atmospheric pressure. The atmospheric pressure Pext forms a stable reference pressure that allows the liquid level NL to be determined accurately in a differential manner.

[0054] Thus, the integration of a sensor 1 in a drain plug allows the level of liquid NL to be measured without modifying the tank 100, which is advantageous. The bulk is furthermore limited.

[0055] According to a second embodiment, with reference to FIG. 4, the measuring device 3 comprises a gas line 32 in fluidic communication with the gas phase PG of the tank 100. In other words, the reference pressure Pref is the gas pressure P2, i.e. the pressure of the gas phase PG. With reference to FIG. 4, the gas line 32 extends externally to the tank 100 and connects the measuring member 30 to an upper opening 103 formed in the tank 100. The gas line 32 may be flexible or rigid. Preferably, the gas line 32 is equipped with pneumatic connections at its ends.

[0056] According to a preferred aspect, the gas line 32 opens into a filler cap (not shown) mounted in a filler port situated in the upper part of the tank 100. The use of a gas line 32 that is flexible makes it possible to avoid its dismantling when the tank 100 is filled. The filler cap may thus be manipulated while remaining connected to the gas line 32. The gas phase PG makes it possible to form a relevant comparison basis for determining the liquid level NL.

[0057] According to another embodiment, with reference to FIG. 5, the gas line 32 extends internally to the tank 100 and the closure device 2 and makes it possible to connect an upper port 104 (tapping) opening into the interior of the tank 100 and the measuring member 30 of the measuring device 3. The internal gas line 32 comprises a first portion 32a that is formed in the thickness of the wall 102 of the tank 100 and a second portion 32b that is formed in the closure device 2. Preferably, the mouthpiece 101 of the tank 100 comprises an opening that allows fluidic communication between the two portions 32a, 32b. Preferably, seals are provided to ensure leak tightness, in particular O-rings.

[0058] In other words, the closure device 2 makes it possible to provide a liquid pressure P1 and a gas pressure P2 in a centralized and practical manner to the measuring device 3. The measuring member 30 thus makes it possible to deduce therefrom the liquid level NL.

[0059] Preferably, the first portion 32a of the gas pipe 32 extends upwards from the upper port 104 and downwards from the opening that allows fluidic communication between the two portions 32a, 32b to avoid any phenomenon of accumulation of liquid mist in the gas pipe 32, which would falsify the measurement.

[0060] According to a preferred aspect, with reference to FIGS. 6 to 8, the measuring device 3 of the sensor 1 comprises two measuring members 30a, 30b in order to perform independent measurements of level NL1, NL2 that are provided to the calculator 6. This advantageously makes it possible to detect in an early manner any defect of one of the measuring members 30a, 30b. Advantageously, the measuring devices 30a, 30b are integrated into a same sensor 1 to reduce the bulk and the number of machining operations in the tank 100. Preferably, each tank 100 is associated with only one sensor 1, this being able to comprise one or more measuring members 30a. 30b. Due to the redundancy, it is no longer necessary to provide a window in the tank 100 in order to allow a visual check of the liquid level NL.

[0061] As illustrated in FIG. 6, the two measuring members 30a, 30b each make it possible to measure a fluid pressure P1 and an external pressure Pext. In this example, the two measuring members 30a, 30b are supplied separately in order to guarantee the independence of the measurements. Nevertheless, it goes without saying that communication with the liquid phase PL or the external medium Mext could be common in order to limit the bulk.

[0062] With reference to FIG. 7, the two measuring members 30a, 30b each make it possible to measure a fluid pressure P1 and a gas pressure P2. In this example, the two measuring members 30a, 30b are supplied separately in order to guarantee the independence of the measurements. However, it goes without saying that communication with the liquid phase PL or the gas phase PG could be common in order to limit the bulk.

[0063] With reference to FIG. 8, the first measuring member 30a makes it possible to measure a fluid pressure P1 and a gas pressure P2 whereas the second measuring member 30b makes it possible to measure a fluid pressure P1 and an external pressure Pext. The use of two reference pressures of different natures makes it possible to obtain two level measurements NL1, NL2 that are independent and decorrelated. This makes it possible to detect a drift of one of the measuring members 30a, 30b or another fault in a practical manner. Indeed, when the turbomachine is stopped, the pressures P2 and Pext must be identical and lead to the same liquid level measurement NL1, NL2.

[0064] The calculator 6 can thus consolidate the level measurements NL1, NL2 (average, etc.) in order to provide qualitative information to the aircraft propulsion system or to the pilot.

[0065] Optionally, the density of the liquid (here the oil density) is also determined. Such information is important given that a same turbomachine may be used with oils of different natures. By knowing the oil type, it is possible to determine a correction parameter ANL1 of the level measurement NL and thus improve the measuring accuracy.

[0066] With reference to FIG. 9, an auxiliary pressure sensor 4 is placed in fluidic communication with the liquid phase via an upper opening 104 of the tank 100 and with the external medium Mext having an external pressure Pext in order to perform a differential pressure measurement that is provided to the calculator 6. Given that the vertical distance h between the upper opening 104 and the port 101 is known, the density of the liquid may advantageously be deduced therefrom by the following formula:

[00001]$\begin{array}{cc}=\frac{P_3-P_2}{\mathrm{gh}*\cos \left(\right)}& \left[\mathrm{Math}\text{.1}\right]\end{array}$

[0067] With g being gravity and & the angle formed between the vertical of the aircraft and the gravitational axis.

[0068] Preferably, the density measurement p is performed after filling the tank 100. The density measurement p is stored in the calculator 6 and will be used to determine the correction parameter ANL1 of the level measurement NL. It goes without saying that the density measurement p could be determined more frequently.

[0069] It is also possible to correct the fill level NL as a function of the temperature. For this purpose, an independent measurement of the liquid temperature is made and supplied to the calculator 6 and will be used to determine a correction parameter ANL2 of the level measurement NL.

[0070] Thus, a corrected level measurement NL* is obtained according to the following formula:

[00002]$\begin{array}{cc}\mathrm{NL}*=\mathrm{NL}+\mathrm{NL}1+\mathrm{NL}2& \left[\mathrm{Math}\text{.2}\right]\end{array}$

[0071] Optionally, the measuring device 3 comprises an amplifier member, in particular hydraulic, in order to increase its sensitivity to the liquid pressure P1 and accurately measure any variation. By way of example, the amplification member is in the form of a piston rod, the ends of which have different sections so as to amplify the variations.

[0072] Optionally, the closure device 2 comprises a strainer in order to filter impurities in the liquid, in particular in the automatic sealing member 21.

Method of Use

[0073] The invention also relates to a method of using a sensor 1 mounted in a drain port 101 of an aircraft tank 100. The method of use will be presented in relation to the embodiment of FIG. 5 and applies analogously to the other embodiments.

[0074] In this exemplary embodiment, in the initial position, only the closure device 2 is mounted in the drain port 101. The sealing member 21 is active and prevents any flow of liquid. If emptying is desired, an operator can introduce a tube into the sealing member 21 or act on the control lever 22.

[0075] To perform a measurement of liquid level NL, the operator mounts the measuring device 3 on the closure device 2, which places the measuring member 30 in fluidic communication with the liquid line 20 which has a liquid pressure P1. As illustrated in FIG. 5, the pressure measuring member 30 is also in fluidic communication with the gas phase PG which has a gas pressure P2. Advantageously, the closure device 2 directly enables this fluidic communication.

[0076] The method comprises a step of determining the liquid level NL from the liquid pressure P1 and the gas pressure P2 measured by the measuring member 30. Such a differential measurement is robust.

[0077] Thanks to the integration of the sensor 1 in a drain plug, the liquid level measurement may be implemented in a practical manner on any type of tank 100. The two-part structure of the sensor 1 makes it possible to ensure draining when required while facilitating maintenance given that the measuring device 3 can be removed in a removable manner.

[0078] The invention also relates to a method for detecting operating conditions from the sensor 1 according to the invention, in particular extreme conditions such as a rapid ascent/descent of the aircraft (abrupt change in altitude).

[0079] Indeed, during a rapid ascent/descent of the aircraft, the liquid housed in the tank 100 is subjected to weightlessness forces, which modify the pressures measured by the sensor 1.

[0080] According to an exemplary embodiment, when the pressure difference is zero, the method comprises a step of emission of an alarm that is provided with the measurement of the liquid level NL or replaces it in order to inform the propulsion system or the pilot of the aircraft that the measurement of the liquid level NL is unreliable given the exceptional conditions. Thus, the differential measurement is taken advantage of to check the operating conditions and to deduce therefrom a relevance rating of the measurement of the liquid level NL that is provided.