• 专利附录
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    • 专利摘要:
    The assembly includes a pump (14) and at least one purge system (22) of the water contained in a fuel tank (16). The purge system (22) comprises a transport pipe having a venturi and a sampling pipe, integral with the transport pipe, extending between a sampling inlet and a sampling outlet, the sampling inlet opening into a region (36) of the reservoir (16) suitable for accumulating water, the sampling outlet opening into the transport pipe, upstream or into the venturi. The pump (14) is arranged downstream of the venturi, and at least one region of the sampling line comprising the sampling outlet is coaxial with the transport line.
    公开号:FR3084056A1
    申请号:FR1800764
    申请日:2018-07-17
    公开日:2020-01-24
    发明作者:Sebastien Merat
    申请人:Dassault Aviation SA;
    IPC主号:
    专利说明:

    Energy production unit and method for purging the water contained in an associated aircraft tank
    The present invention relates to an aircraft energy production assembly comprising:
    - an energy production device;
    - a pump ;
    - at least one tank containing fuel, the tank comprising a fuel supply line; and
    - at least one system for purging the water contained in the tank, the purging system comprising:
    • a transport line fluidly connected to the supply line, the transport line having at least one fuel suction inlet opening into the tank and a venturi downstream of the fuel suction inlet; and • a sampling pipe, integral with the transport pipe, extending between a sampling inlet and a sampling outlet, the sampling inlet opening into a region of the reservoir suitable for accumulating water, the outlet of sample emerging in the transport pipe, upstream or in the venturi.
    A fuel tank provides an environment conducive to the development of microbial pollution. Over time, water condenses in the fuel and flows to the bottom of the tank. At the interface between water and fuel, microorganisms such as bacteria are likely to grow. These microorganisms, when they proliferate, constitute pollution of the reservoir which is at the origin of its corrosion.
    In order to prevent this proliferation, a known method is to purge the water accumulated in the bottom of the tank by pumping it and diluting it with the fuel to power the propulsion engines of the aircraft. A system for implementing such a method is for example described in document US 2010/0071774.
    However, such a system significantly lacks compactness.
    In addition, the aircraft engines are subject to significant certification constraints, in particular with regard to the permissible water concentration of the fuel supplying them. As an indication, the maximum permissible water concentration for most aircraft engines cannot exceed 0.02% (200 ppm), the minimum required according to current certification regulations. Their use to purge water accumulating at the bottom of fuel tanks is therefore limited.
    The object of the invention is to provide an assembly which makes it possible to purge the water contained in an aircraft tank in a simple manner and which is compact.
    To this end, the subject of the invention is an assembly for producing energy of the aforementioned type, characterized in that the pump is arranged downstream of the venturi, and at least one region of the sampling line comprising the sampling outlet is coaxial with the transport line.
    The set can also include one or more of the characteristics below, taken alone or in any technically possible combination:
    the energy production device is an auxiliary power group, the supply line being intended to supply said auxiliary power group with the fuel contained in said tank, the supply line being connected to the auxiliary power group and connected to the pump;
    - the energy production device is configured so that the nominal flow rate in the supply line is less than 2 L / min;
    - the transport line extends to a free end, the sampling line being received in the transport line passing through the free end of the transport line;
    - the sampling line extends until it is in contact with an interior surface of a wall of the tank, the sampling inlet being defined by a lateral opening, the lateral opening preferably having an open contour;
    - The transport line comprises a retaining neck of the sampling line, the retaining collar enclosing the sampling line;
    - The transport line comprises a suction cone upstream of the venturi, the suction inlet of the transport line being delimited between the retaining neck and the suction cone;
    the assembly according to the aforementioned type comprises a shim for positioning the sampling pipe, the sampling pipe comprising a positioning projection, the positioning shim being interposed between the positioning projection and the retaining neck and being in contact with the positioning projection and the retaining collar;
    - the supply line is directly connected to the energy production device without an intermediate reservoir between the two;
    the assembly according to the aforementioned type comprises at least one additional tank and an additional purge system for the water contained in the additional tank, the assembly further comprising a control valve associated with each supply line, each valve control having an opening configuration and a closing configuration of the supply line with which it is associated;
    - The assembly according to the aforementioned type further comprises a processing unit configured to successively open each control valve for a predetermined period of time, the processing unit being configured to authorize the opening of only one of said control valves by predetermined period of time;
    - the assembly does not have any other pump connected to the supply line;
    - said tank defines an internal volume located outside the additional tank;
    - the supply line has no recirculation loop; and
    - the region located upstream of the venturi and the sampling line do not have a pump.
    The invention also relates to a process for purging the water contained in an aircraft fuel tank comprising the steps of:
    - supply of a set according to the aforementioned type;
    - pump activation; and
    - purging by suction of the water contained in the tank, this purging by suction step comprising the sub-steps of:
    - suction of the fuel by the suction inlet of the transport pipe, and flow of the sucked fuel towards the energy production device via the supply pipe; and
    - aspiration of water through the sampling inlet of the sampling line, and flow of the sucked water towards the energy production device via the supply line.
    The process can also include one or more of the characteristics below, taken alone or in any technically possible combination:
    - during the water suction stage, the pressure difference between the suction inlet and the sampling inlet is equal to the hydrostatic pressure difference between the suction inlet and the inlet direct debit;
    the water suction sub-step via the sampling inlet is only implemented when the flow rate in the supply line is greater than a minimum dilution rate, the minimum rate of dilution being greater than 110% of a minimum operating flow that the energy production device is able to impose in the supply line, the flow rates being advantageously volume flow rates;
    - The assembly includes at least one additional tank and an additional purge system of the water contained in the additional tank; the assembly further comprising a control valve associated with each supply line, each control valve having an opening configuration and a closing configuration of the supply line with which it is associated;
    the method successively comprising purging by suction of the water contained in each tank by the successive opening of each control valve for a predetermined period of time, only one of said control valves being open per predetermined period of time.
    The invention also relates to an aircraft power generation assembly comprising: an auxiliary aircraft power unit; a pump ; at least one tank containing fuel, the tank comprising a fuel supply line; and at least one system for purging the water contained in the tank, the purging system comprising:
    • a transport line fluidly connected to the supply line, the transport line having at least one fuel suction inlet opening into the tank and a venturi downstream of the fuel suction inlet; and • a sampling pipe, integral with the transport pipe, extending between a sampling inlet and a sampling outlet, the sampling inlet opening into a region of the reservoir suitable for accumulating water, the outlet of sample emerging in the transport pipe, upstream or in the venturi;
    the assembly being characterized in that the supply line is intended to supply said auxiliary group with the fuel contained in said tank, the supply line being connected to the auxiliary group and connected to the pump.
    The entire energy production does not necessarily include the characteristics according to which the pump is arranged downstream of the venturi, and at least one region of the sampling line comprising the sampling outlet is coaxial with the transport line.
    The set may include one or more of the characteristics defined above, taken alone or in any technically possible combination.
    The invention will be better understood on reading the description which follows, given solely by way of example, and made with reference to the appended drawings, in which:
    - Figure 1 is a schematic view of a first aircraft power generation assembly according to the invention;
    - Figure 2 is a schematic perspective view of a purge system of the assembly of Figure 1;
    - Figure 3 is a schematic sectional view of the purge system of Figure 2;
    - Figure 4 is a schematic sectional view of a locking and unlocking tool of the valve of the purge system of Figure 2 in the release configuration;
    - Figures 5 and 6 are schematic sectional views of the purge system of Figure 2 during a process of purging the water contained in the tank;
    - Figure 7 is a schematic view of a variant of the first assembly according to the invention;
    - Figure 8 is a view similar to Figure 1 of a second assembly of aircraft energy production according to the invention; and
    FIG. 9 is a schematic sectional view of the purge system of the second set of FIG. 8.
    The invention relates to an aircraft comprising a first assembly 10A for producing aircraft energy illustrated in FIG. 1.
    The first energy production assembly 10A comprises an energy production device 12 of the aircraft, a pump 14 and at least one fuel tank 16, the tank 16 comprising a wall 18 and a supply line 20 for fuel.
    The first assembly 10A also includes a purge system 22 of the water contained in the tank 16.
    The energy production device 12 is capable of producing energy from the fuel contained in the tank 16.
    In the first assembly 10A, the energy production device 12 is for example one of the engines of the aircraft or an auxiliary power unit of the aircraft ("Auxiliary Power Unit" or "APU").
    The pump 14 is connected to the supply line 20 and is capable of circulating a fluid inside the supply line 20.
    For this purpose, the pump 14 is dimensioned so as to be able to supply the flow rate requested by the energy production device 12 throughout its operating speed range.
    Via the pump 14, the energy production device 12 is thus capable of imposing in the supply line 20 a minimum operating flow and a maximum operating flow.
    In the case where the energy production device 12 is an aircraft engine, it is capable of imposing a nominal flow rate of fuel supplying the engine greater than 3 L / min.
    As illustrated in FIG. 1, the tank 16 contains fuel 24 and water 26. The water 26 typically comes from a phenomenon of condensation and is collected by gravity at the bottom of the tank 16.
    Microorganisms, such as bacteria, are capable of growing in the reservoir 16, more precisely at the interface between the water 26 and the fuel 24. These microorganisms are liable to proliferate and to constitute microbial pollution of the reservoir 16.
    The wall 18 of the reservoir 16 has an interior surface 28 and an exterior surface 30, the interior surface 28 defining an internal volume 34 of the reservoir 16.
    The wall 18 defines a through opening 32 disposed in a region 36 of the tank 16 in which the water 26 accumulates by gravity due to its condensation.
    The supply line 20 is intended to supply said energy production device 12 with the fuel 24 contained in the tank 16.
    For this, the supply line 20 is fluidly connected to the energy production device 12 and to the pump 14.
    The supply line 20 is also at least partially disposed inside the internal volume 34 of the tank 16, and passes through the wall 18. It passes through it through an opening separate from the through opening 32.
    The supply line 20 has an open end 38 opening into the tank 16.
    As illustrated in FIGS. 2 and 3, the supply line 20 widens towards the open end 38 to form a cone 40.
    Downstream of the cone 40, the supply line 20 has a reception region 42 of the purge system 22 as described in more detail below. Here and thereafter, the terms "upstream" and "downstream" will be understood with respect to the normal direction of flow of the fuel when the pump 14 is started to supply the energy production device 12.
    The reception region 42 has a substantially constant internal section, the cone 40 extending from the reception region 42 towards the open end 38.
    The supply line 20 also includes a fixing support 43 to the wall
    18.
    In the example illustrated in FIG. 2, the fixing support 43 is a plate having through holes and extending from an outer surface of the cone 40. The plate is fixed to the wall 18.
    The purge system 22 of the first set 10A is illustrated in more detail in FIGS. 2 and 3.
    The purge system 22 comprises a transport line 44 fluidly connected to the supply line 20, and intended to suck the fuel 24 contained in the tank 16 and to flow it towards the supply line 20 to supply the device for energy production 12.
    The purge system 22 also advantageously comprises a sampling line 46, intended to suck up the water 26 accumulating at the bottom of the tank 16 and to flow it towards the transport line 44, to supply the energy production device 12 with fuel having a controlled water concentration.
    Furthermore, in the first assembly 10A, the purge system 22 comprises a body 48 mounted on the reservoir 16 and a valve 50 received in the body 48.
    The transport line 44 extends between at least one fuel intake inlet 52 and a fuel ejection outlet 54.
    In the example of FIG. 3, the transport pipe 44 extends along a longitudinal axis A and is centered on this longitudinal axis A.
    In the example illustrated in FIG. 3, the transport pipe 44 has a plurality of suction inlets 52.
    In the first set 10A, each suction inlet 52 is defined by a lateral opening 56 formed in the transport line 44.
    The transport pipe 44 extends towards the body 48 along the longitudinal axis A including beyond each suction inlet 52. In other words, the transport pipe 44 does not stop longitudinally at the level suction inlets 52. The transport pipe 44 extends longitudinally to a free end where it stops longitudinally, this free end being located at a distance and upstream from the suction inlets 52.
    All of said suction inlets 52 are arranged at the same level along the longitudinal axis A. In particular, they are superimposed on each other in projection on the longitudinal axis A.
    Each suction inlet 52 is disposed above a maximum estimated level of water 26 which can be accumulated in the tank 16 for a predetermined period of time. Thus, only the fuel is sucked in by the suction inlets 52. Here and thereafter, the terms "upper", "lower", "above", and "below" will be understood with reference to the axis longitudinal A.
    Each suction inlet 52 is arranged outside the body 48, in the sense that in projection along the longitudinal axis A, no suction inlet 52 is superimposed on the body 48.
    In particular, in projection on the longitudinal axis A, each suction inlet 52 is disposed between the body 48 and the ejection outlet 54 of the transport pipe 44.
    The transport line 44 is received in the open end 38 of the supply line 20.
    In particular, the transport pipe 44 is received in the reception region 42 of the supply pipe 20, the reception region 42 sealingly enclosing the transport pipe 44.
    The cone 40 of the supply line 20 thus forms a guide cone of the transport line 44, the guide cone 40 surrounding the transport line 44.
    At least one region of the transport line 44 comprising the ejection outlet 54 is coaxial with a region of the supply line 20 comprising the open end 38 and the reception region 42 of the supply line 20.
    The ejection outlet 54 opens into the supply line 20.
    The ejection outlet 54 is formed by an open upper end 58 of the transport pipe 44. This upper end 58 is arranged in the reception region 42.
    An O-ring 60, integral with the transport line 44, comes into contact with the supply line 20, at the level of the reception region 42, to ensure sealing between the transport lines 44 and supply line 20 As a variant, this O-ring 60 is integral with the supply line 20.
    The transport line 44 has a venturi 62 downstream of the fuel suction inlets 52.
    More specifically, the venturi 62 is disposed between the ejection outlet 54 on the one hand and the suction inlets 52 on the other hand. The venturi 62 is thus arranged downstream of the free end of the transport pipe 44.
    The venturi 62 is formed in the transport line 44 by a region of decreasing internal section 64 towards the ejection outlet 54, a region of constant internal section 66 extending from the region of decreasing internal section 64, and a increasing internal section region 68 towards the ejection outlet 54 extending from the constant internal section region 66.
    As illustrated in Figure 3, the pump 14 is downstream of the venturi.
    The presence of a pump 14 disposed downstream of the venturi, and the coaxiality of the region of the transport line 44 comprising the ejection outlet 54 with a region of the supply line 20 comprising the open end 38 and the reception region 42 of the supply line 20 together ensure maximum compactness in the tank 16, limiting the radial size.
    As illustrated in FIG. 3, the body 48 is mounted on the reservoir 16 at least partially through the through opening 32.
    The body 48 extends along the longitudinal axis A.
    It includes an outlet channel 70, a central guide channel 72 and lateral fins 74.
    The outlet channel 70 is hollow and opens out to the outside of the tank 16. It is thus arranged at least in part outside of the tank 16.
    In the example of FIG. 3, the outlet channel 70 is formed by a part separate from the central channel 72 and the fins 74, and is fixed to the rest of the body 48.
    The outlet channel 70 is preferably cylindrical, for example of circular section. It extends along the longitudinal axis A and is centered on this axis A.
    The outlet channel 70 is in particular coaxial with the transport line 44.
    In the example of FIG. 3, the outlet channel 70 defines a valve seat 76 suitable for cooperating with the valve 50.
    The valve seat 76 corresponds more precisely to a surface of the outlet channel 70 disposed at an upper end 78 of the outlet channel 70.
    The valve seat 76 is in this example of frustoconical shape.
    The central guide channel 72 is arranged partly inside the tank 16 and partly outside the tank 16.
    The central channel 72 is preferably cylindrical, for example of circular section. It extends along the longitudinal axis A and is centered on this axis A.
    The central channel 72 is in particular coaxial with the transport pipe 44 and the outlet channel 70. It extends in the extension of the outlet channel 70.
    The central channel 72 is fixed to the transport pipe 44.
    In the example illustrated in FIG. 3, the central channel 72 defines a shoulder in contact with a part of the upper end 78 of the outlet channel 70.
    In a typical aircraft ground maneuver, the outlet channel 70 is arranged below the central channel 72, with respect to a vertical axis typical of the aircraft.
    The central channel 72 has at least one lateral opening 80 passing through. Preferably, the central channel 72 has a plurality of lateral orifices 80.
    Each lateral orifice 80 is disposed inside the tank 16 and preferably at least partially opposite an edge of said through opening 32.
    In the example of FIG. 3, a lower edge 82 of each lateral orifice 80 is disposed, along the longitudinal axis A, below the interior surface 28 of the wall 18 of the reservoir 16 at the level of the opening through 32.
    The fins 74 extend from the central channel 72 perpendicular to the longitudinal axis A. They are arranged outside the tank 16.
    The fins 74 have come here integrally with the central channel 72.
    The fins 74 are attached against the external surface 30 of the wall 18 of the tank 16. They are fixed to the wall 18 of the tank 16 by a sealed fixing device 84.
    In addition, the body 48 comprises an O-ring 86 disposed between the fins 74 and the outer surface 30 of the wall 18. This O-ring 86 surrounds the through opening 32 and makes it possible to seal between the body 48 fixed to the wall 18 and the wall 18.
    The valve 50 comprises at least one base 88 and an O-ring seal 90.
    Said base 88 has an external surface 92 complementary to the valve seat 76.
    The O-ring seal 90 is disposed on said outer surface 92 complementary to the base 88. The O-ring seal 90 is for example integral with the base 88.
    The valve 50 has a configuration for releasing the outlet channel 70 and a sealed closure configuration for the outlet channel 70, illustrated in FIG. 3.
    In the embodiment shown, the valve 50 is movable relative to the body 48.
    It is partly arranged in the central channel 72 and is able to slide in the central channel 72. The valve 50 is also partly arranged in the outlet channel 70 and is suitable for sliding in the outlet channel 70.
    In the release configuration of the valve 50, the outlet channel 70 is in fluid communication with the interior of the reservoir 16, in particular through the lateral orifices 80 of the central channel 72 of the body 48.
    In the release configuration, the valve 50 is arranged away from the valve seat 76. In particular, said external surface 92 complementary to the base 88 and the O-ring seal 90 are away from the valve seat 76.
    In the obturation configuration, the outlet channel 70 is capable of being fluidly isolated from the interior of the reservoir 16, in particular fluidically isolated from the lateral orifices 80.
    In the obturation configuration, the valve 50 obstructs the outlet channel 70. The valve 50 is in contact with the valve seat 76. In particular, said external surface 92 complementary to the base 88 is applied to the valve seat 76. In addition, the O-ring seal 90 is in contact with the valve seat 76 to seal the closure.
    As illustrated in FIG. 3, a return device 94, included in the purge system 22, is capable of returning the valve 50 to its sealed closure configuration.
    The return device 94 preferably comprises a spring 96 having an upper end fixed to the body 48 and a lower end fixed to the valve 50.
    The lower end of the spring 96 is in particular fixed to said base 88.
    In the embodiment of FIG. 3, the spring 96 is fixed to the body 48 by means of a support piece 98 fixed to the central channel 72, the support piece 98 being received at least partly in the channel central 72.
    In addition, as illustrated in FIG. 3, the base 88 also has an external face 100, received in the outlet channel 70 when the valve 50 is in its sealed closure configuration.
    The external face 100 is substantially flat, extends perpendicular to the longitudinal axis A and is directed towards the outside of the tank 16.
    The external face 100 has a hollow spherical imprint 102.
    In the example of the first assembly 10A illustrated in FIG. 3, the sampling line 46 is formed by the valve 50, the sampling line 46 thus being at least partly mounted in the body 48. For this, the valve 50 comprises furthermore, a nozzle 104 extending from said base 88 towards the transport pipe 44.
    More specifically, the nozzle 104 and said base 88 form the sampling line 46, the nozzle 104 being hollow and said base 88 defining an internal chamber 106 opening onto the interior of the nozzle 104.
    The nozzle 104 here extends along the longitudinal axis A.
    In this example, it came integrally with said base 88.
    The nozzle 104 has an external section smaller than the internal section of the region of constant internal section 66 of the venturi 62.
    The nozzle 104 passes through the spring 96 and the support piece 98 of the spring 96, the spring 96 being arranged around the nozzle 104.
    The internal chamber 106 of the base 88 has a bottom 108 extending perpendicularly to the longitudinal axis A.
    The sampling line 46 extends between a sampling inlet 110, defined here in the base 88, and a sampling outlet 112, defined here by the nozzle 104.
    At least one region of the sampling line 46 comprising the sampling outlet 112 is coaxial with the transport line 44. The space requirement is therefore limited.
    The sampling line 46 is received in the transport line 44 passing through the free end of the transport line 44.
    The sample outlet 112 opens into the transport line 44, upstream or into the venturi 62. The sample outlet 112 is thus for example arranged in the region of decreasing internal section 64 or in the region of constant internal section 66.
    The sampling outlet 112 is here formed by an open upper end of the nozzle 104.
    In projection on the longitudinal axis A, the sampling outlet 112 is arranged between the ejection outlet 54 of the transport pipe 44 and each suction inlet 52.
    In the example illustrated in FIG. 3, the sampling line 46 has a plurality of sampling inputs 110.
    Each sampling inlet 110 is defined by a lateral opening 114 in the base 88 of the valve 50, the lateral opening 114 opening into the internal chamber 106 of the base 88.
    The sampling inlets 110 each have a lower edge 116. As illustrated in FIG. 3, each lower edge 116 and the bottom 108 of the internal chamber 106 are situated substantially in the same horizontal plane.
    In the shutter configuration of the valve 50, each sampling inlet 110 is at least partially opposite a lateral orifice 80 of the central channel 72.
    In addition, in the shutter configuration of the valve 50, each sampling inlet 110 opens at least partially opposite an edge of said through opening 32.
    More specifically, in the obturation configuration, the lower edge 82 of each lateral orifice 80 of the central channel 72, the lower edge 112 of each sampling inlet 110 and the bottom 108 of the internal chamber 106 are located substantially in the same plane .
    In addition, as illustrated in FIG. 3, in the shutter configuration, the bottom 108 of the internal chamber 106 of the base 88 is arranged, along the longitudinal axis A, below the interior surface 28 of the wall 18 of the reservoir 16, in the vicinity of the through opening 32. The water accumulating at the bottom of the reservoir 16 is thus capable of filling the internal chamber 106 by gravity.
    The sampling line 46 is separate from the transport line 44 and has no contact with the transport line 44.
    In the first set 10A, the purge system 22 is capable of carrying out a purge by gravity flow of the water 26 contained in the tank 16.
    To carry out this purge by gravity flow from the reservoir 16, a purge kit according to the invention is advantageously provided. The kit includes the purge system 22 described above, and a tool 152 for locking and unlocking the valve 50 in the release configuration.
    This tool 152 is illustrated in more detail in FIG. 4.
    The tool 152 comprises a discharge pipe 154 and a push rod 156.
    The evacuation pipe 154 is suitable for being removably attached to the body 48 of the purge system 22.
    When the discharge line 154 is fixed to the body 48, the interior of the discharge line 154 and the outlet channel 70 are in fluid communication.
    In the example illustrated in FIGS. 3 and 4, the evacuation pipe 154 and the outlet channel 70 each comprise a thread, the threads being able to cooperate to ensure the removable fixing of the evacuation pipe 154 on the body 48.
    The rod 156 is integral with the evacuation pipe 154, by means of a support structure 158 suitable for letting a liquid pass.
    The rod 156 protrudes relative to the evacuation pipe 154, and has an external end 158 suitable for coming into contact with the valve 50, for pushing it and for maintaining it in its release configuration when the evacuation pipe 154 is fixed on the body 48.
    The rod 156 is received in the outlet channel 70 when the evacuation pipe 154 is fixed to the body 48.
    Preferably, the external end 158 of the rod 156 has a shape complementary to the spherical imprint 102 of the external face 100 of the valve 50.
    The outer end 158 thus has the shape of a hemisphere.
    The rod 156 is preferably made of plastic.
    The mounting of the purge system 22 on the aircraft fuel tank 16 according to the invention will now be described.
    This assembly includes the supply of the aircraft fuel tank 16 and the supply of the purge system 22.
    The purge system 22 is initially disposed away from the tank 16, and the tank 16 is initially empty of fuel.
    The transport line 44 is inserted by an operator into the through opening 32 and then connected to the supply line 20 of the tank 16.
    The connection includes guiding the transport line 44, through the cone 40 of the supply line 20.
    This guidance by the cone 40 facilitates connection. Indeed, the operator cannot see the inside of the tank 16 and the connection is therefore made blind by the operator from outside the tank 16.
    At the end of this connection, the ejection outlet 54 opens into the supply line 20 and each suction inlet 52 opens into the tank 16.
    In parallel with the insertion of the transport pipe 44, the body 48 of the purge system 22 is mounted on the reservoir 16 at least partially through the through opening 32.
    The body 48 is then fixed on the tank 16. During this fixing, the fins 74 are attached against the wall 18 of the tank 16 and fixed to the wall 18 of the tank 16 by the sealed fixing device 84.
    Thus, the purge system 22 does not require any adaptation of the current tanks to allow its mounting, and can easily replace the existing purge systems.
    As a result, once the purge system 22 mounted on the fuel tank 16, the tank 16 is filled with fuel and the first set 10A of energy production according to the invention is obtained.
    If necessary, the purge system 22 can be dismantled from the outside, for example for checking or cleaning.
    A method of purging the water 26 contained in the fuel tank 16 according to the invention can then be implemented.
    In operation, in particular when the aircraft is stationary on the ground, the purging process comprises purging by gravity flow of the water 26 contained in the tank 16.
    Advantageously, the purge by gravity flow is implemented with the tool 152 for locking and unlocking the purge kit described above.
    Preferably, the purge by gravity flow is preceded by the carrying out of a preliminary sampling intended to note or not the presence of water in the tank 16. This sampling is illustrated in FIG. 5.
    To carry out this preliminary sampling, an operator passes the valve 50 from its sealed shutter configuration to its release configuration, the valve 50 being initially in its shutter configuration.
    For this, the operator brings the external end 158 of the rod 156 into contact with the valve 50. The external end 158 is received in the spherical cavity 102 of the external face 100 of the valve 50.
    As illustrated in FIG. 5, the operator moves the tool 152 so as to change the valve 50 from its shutter configuration to its release configuration.
    In particular, the tool 152 is moved longitudinally towards the valve 50 in the direction of the longitudinal axis A.
    The liquid contained in the reservoir 16 passes through each lateral orifice 80 of the central channel 72 of the body 48, and flows towards the outlet channel 70 and outside the reservoir 16.
    The operator collects with a suitable container the liquid which flows out of the reservoir 16 through the outlet channel 70.
    Once a sufficient quantity of liquid to form a sample has passed, the operator resets the valve 50 from its release configuration to its obturation configuration.
    The tool 152 is therefore moved opposite the valve 50. The return device 94 spontaneously recalls the valve 50 in its sealed closure configuration.
    The operator examines the sample and if the spilled liquid contains water, the operation is repeated in the same way until the sample contains only fuel.
    For this, as illustrated in FIG. 6, the operator again switches the valve 50 from its shutter configuration to its release configuration in a similar manner.
    The evacuation pipe 154 is then fixed to the body 48 of the purge system 22.
    For this, it is screwed onto the thread of the outlet channel 70. The valve 50 is thus locked in its release configuration. In other words, as long as the evacuation pipe 154 is fixed to the body 48, the valve 50 is maintained in the release configuration.
    The tool 152 can thus be easily manipulated by the operator, and greatly reduces the risks of inadvertent locking of the valve in the release configuration.
    Thanks to the spherical shape of the impression of the valve 50 and of the external end 158 of the rod 156, the impression 102 is not damaged by contact with the external end 158 of the rod 156, in particular during the screwing of the discharge pipe 154 on the outlet channel 70. In the case where the rod 156 is made of plastic, the imprint 102 is even less damaged.
    When the evacuation pipe 154 is fixed to the body 48, the valve 50 is for example further away from the valve seat 76 than during the preliminary sampling.
    The interior of the evacuation pipe 154 and the outlet channel 70 are thus in fluid communication and the water 26 contained in the tank 16 then flows into the outlet channel 70 and then into the evacuation pipe 154.
    This water is also collected with an appropriate container.
    When the operator finds that there is only fuel 24 flowing out of the tank 16 through the outlet channel 70, the operator removes the valve 50 from its release configuration to its configuration d shutter.
    For this, it unscrews the evacuation pipe 154 and moves the tool 152 opposite the valve 50 until the return device 94 recalls the valve 50 in its sealed closure configuration.
    The purge by gravity flow thus constitutes a first way of evacuating the water 26 contained in the tank 16 by using the purge system 22 of the first set 10A according to the invention.
    In addition, in operation, the purging method comprises a step of purging by suction of the water 26 contained in the tank 16 which constitutes a second way of evacuating the water 26 contained in the tank 16.
    This suction purge is implemented when the energy production device 12 is started. It is therefore in particular implemented when the aircraft is on the ground, the energy production device 12 being activated, when it performs a maneuver on the ground or a take-off or landing maneuver or when it is in flight. This suction purge is also implemented when the aircraft is stopped from the moment when the energy production device 12 is started.
    During the purge by suction, the valve 50 is preferably in the obturation configuration.
    The suction purge comprises the suction of the fuel 24 by the suction inlet 52 of the transport line 44. The sucked fuel 24 flows from each suction inlet 52 to the ejection outlet 54, then to the energy production device 12 via the supply line 20.
    During the purge by suction, the water 26 is sucked in by each sample inlet 110 of the sample line 46.
    More specifically, when the fuel 24 is sucked into the transport line 44, the venturi 62 creates a vacuum by venturi effect, this vacuum depending on the flow rate in the supply line 20. Since the sampling line 46 opens upstream or into the venturi 62, when the flow rate in the supply line 20 is sufficient, the vacuum created by the venturi 62 is sufficient to draw the water 26 from each sampling inlet 110.
    In other words, the suction of water 26 through each sampling inlet 110 is implemented only when the flow rate in the supply line 20 is greater than a minimum dilution rate. In particular, the minimum dilution rate is greater than 110% of a minimum operating rate that the energy production device 12 is able to impose in the supply line 20.
    As the pump 14 is arranged downstream of the venturi, during the suction of the water 26, the pressure difference between one of the suction inlets 52 and one of the sampling inlets 110 is also equal to the difference in hydrostatic pressure between this suction inlet 52 and this sampling inlet 110. By "pressure at the suction inlet" is meant, for example, the pressure presented by the fuel taken at the center of the contour of the lateral opening 56 defining this inlet suction. By "pressure at the sample inlet" is meant for example the pressure presented by the water taken at the center of the contour of the lateral opening 114 defining this sample inlet.
    Thereafter, the water 26 sucked in flows from the sampling inlet 110 to the sampling outlet 112 to open into the transport line 44, then opens into the supply line 20 via the ejection outlet 54 and flows with the fuel 24 to the energy production device 12 via the supply line 20.
    The minimum dilution rate depends on the dimensions of the venturi 62 and on the dimensions of the sampling line 46.
    The water concentration in the fuel 24 flowing in the supply line 20 depends on the flow rate in the supply line 20.
    Thus, fuel 24 having a controlled water concentration supplies the energy production device 12, which makes it possible to purge the water 26 contained in the tank 16.
    If the water 26 contained in the tank 16 freezes, for example because of the temperature conditions in flight, the purge system 22 will only suck fuel 24 and the energy production device 12 will always be supplied. The purge system 22 described is thus robust against freezing.
    As a variant, the purge system 22 can also be used during a maintenance operation, to carry out a complete emptying of the tank 16 by gravity flow. For this, the valve 50 is maintained and locked in its release configuration as previously described, until nothing more flows out of the tank 16. For example, the valve 50 is locked in this configuration for one to two hours.
    In addition to the first set 10A, illustrated in FIG. 7, the first set 10A comprises at least one additional tank 200 and an additional purge system 202 of the water contained in the additional tank 200, similar to the tank 16 and to the purge 22 described above.
    The additional tank 200 also includes an additional supply line 203, connected to the pump 14. The pump 14 is suitable for circulating a fluid inside the additional supply line 203.
    The additional supply line 203 is intended to supply said energy production device 12 with the fuel 24 contained in the additional tank 200. For this, the additional supply line 203 is fluidly connected to the energy production device 12 and pump 14.
    The additional supply line 203 is here connected to the supply line 20 of the reservoir 16, for example upstream of the pump 14.
    Said tank 16 defines an internal volume 204 located outside of or each additional tank 200.
    The first assembly 10A then further comprises a control valve 206 associated with each supply line 20, 203, each control valve 206 having an opening configuration and a closing configuration of the supply line 20, 203 to which it is associated.
    Each control valve 206 is thus associated with a tank 16, 200. In its closed configuration, each control valve 206 is capable of preventing the flow, towards the energy production device 12, of the fuel 24 coming from the tank 16, 200 with which it is associated.
    The first assembly 10A further comprises a processing unit 208.
    The processing unit 208 comprises a processor 210 and a memory 212, the processor 210 being adapted to execute modules contained in the memory 212.
    The memory 212 includes a module 214 for managing the opening of the control valves 206.
    The module 214 for managing the opening of the control valves 206 is configured to open each control valve 206 in a loop and successively for a predetermined period of time.
    The predetermined period of time is for information greater than 30 seconds, preferably between 1 min and 3 min.
    The module 214 for managing the opening of the control valves 206 is configured to authorize the opening of only one of said control valves 206 per predetermined period of time.
    In operation, the purge method successively comprises and in a loop the purge by suction of the water 26 contained in each reservoir 16, 200 by the successive opening of each control valve 206 for a predetermined period of time, only one of said valves 206 being opened by a predetermined period of time.
    The purge process is implemented by the module 214 for managing the opening of the control valves 206.
    In the embodiment of the invention above, the module 214 for managing the opening of the control valves 206 is produced in the form of software stored in the memory 212. As a variant, the module 214 for managing the opening of the control valves 206 is made at least partially in the form of programmable logic components, or even in the form of dedicated integrated circuits.
    In a variant not illustrated in FIG. 7, the first assembly 10A comprises a plurality of other additional tanks and a control valve per additional tank similar to those described above.
    As a variant, the transport line 44 has only one suction inlet 52.
    As a variant, the O-ring seal 90 of the valve 50 is integral with the outlet channel 70.
    In a variant not shown, the sampling line 46 is formed from a separate part from the valve 50. The sampling line 46 thus remains fixed when the valve moves during the purge by gravity flow.
    As a variant of the first system, the purge system 22 does not have a sampling line 46. The first assembly 10A is then suitable for carrying out only a purging by gravity flow, while having good compactness due to the fact that the supply line 20 and the transport line 44 are integral.
    As a variant, the purge by gravity flow is implemented by any other suitable purge kit.
    A second assembly 10B according to the invention will now be described, with reference to FIGS. 8 and 9.
    This second set 10B differs from the first in that the sampling line 46 is not formed by a valve but is integral with the transport line 44. As illustrated in FIG. 9, the purge system 22 of the second set 10B is in particular without the body 48 and the valve described above. The sampling line 46 is mounted fixed relative to the transport line 44.
    The transport pipe 44 comprises a retaining neck 250 of the sampling pipe 46, the retaining neck 250 enclosing the sampling pipe 46.
    The retaining neck 250 has a length, taken along the longitudinal axis A, for example greater than 10 mm.
    Unlike the first set 10A, the suction inlets 52 are not defined by lateral openings in the transport line 44.
    The transport line 44 thus extends to a lower open end 252, each suction inlet 52 being defined at this lower open end 252.
    More specifically, the transport pipe 44 comprises a suction cone 254 upstream of the venturi 62, each suction inlet 52 of the transport pipe 44 being delimited between the retaining neck 250 and the suction cone 254.
    In the example illustrated in FIG. 9, the suction cone 254 extends from the region of constant internal cross-section 66 of the venturi 62, to the free end of the transport pipe 44. Thus, this suction cone 254 defines the region of decreasing internal section 64 of the venturi 62.
    The retaining neck 250 is in particular received in the suction cone 254 and is connected to the suction cone 254 by rods.
    The rods are straight and extend perpendicular to the longitudinal axis A between the retaining neck 250 and the suction cone 254.
    Preferably, the retaining neck 250, the rods and the suction cone 254 have come in one piece.
    Each suction inlet 52 is defined between the rods connecting the retaining neck 250 to the suction cone 254.
    Unlike the first set 10A, the sampling line 46 extends until it is in contact with the internal surface 28 of the wall 18 of the tank 16, in the region 36 of the tank 16 suitable for accumulating water 26 s 'flowing by gravity due to its condensation.
    The wall 18 of the reservoir 16 is devoid of a through opening 32 opposite the sampling pipe 46, that is to say at the intersection of the longitudinal axis A and the wall 18.
    As in the first set 10A, each sample inlet 110 is always defined by a lateral opening 114, the lateral opening 114 having in the second set 10B an open contour as illustrated in FIG. 9.
    In operation, as before, the pressure difference between one of the suction inlets 52 and one of the sampling inlets 110 is also equal to the difference in hydrostatic pressure between this suction inlet 52 and this sampling inlets 110. At the Unlike what has been described above, by "pressure at the suction inlet" is meant here for example the pressure presented by the fuel taken at the free end of the transport line 44. By "pressure at the 'sampling inlet' means for example the pressure presented by the water taken at the center of the open contour of the lateral opening 114 defining this sampling inlet.
    The second assembly 10B also includes a positioning wedge 256 of the sampling line 46.
    The positioning wedge 256 makes it possible to adjust the position, along the longitudinal axis A, of the sampling line 46 relative to the transport line 44.
    The positioning wedge 256 encloses the sampling line 46. It has an internal section substantially complementary to an external section of the sampling line 46.
    The length of the positioning shim 256, taken along the longitudinal axis A, is for example greater than 2.5 mm.
    The length of the positioning wedge 256 makes it possible to precisely choose the position of the sample outlet 112 in the transport line 44, and therefore to define the minimum cross-section of the fuel between the internal part of the transport line 44 and the external surface of the sampling line 46.
    The sampling line 46 comprises a positioning projection 258, the positioning wedge 256 being interposed between the positioning projection 258 and the retaining neck 250 and being in contact with the positioning projection 258 and the retaining neck 250.
    The positioning projection 258 extends in particular laterally from the outer section of the sampling line 46.
    In the second assembly 10B, the supply line 20 is directly connected to the energy production device 12 without an intermediate reservoir between the two.
    In addition, the assembly does not have any other pump connected to the supply line 20.
    In particular, the region located upstream of the venturi 62 and the sampling line 46 are devoid of pump.
    In the second set 10B, the purge system 22 is thus only suitable for implementing a purge by suction of the water 26 contained in the tank
    16. It is not suitable for implementing a purge by gravity flow of the water 26 contained in the reservoir 16.
    When the energy production device 12 of the first set 10A or of the second set 10B is an auxiliary power unit, in normal operation, the flow rate in the supply line 20 is then preferably less than 2 L / min.
    Typically, aircraft engines and auxiliary power units in service are certified to allow a maximum concentration of water in fuel of 0.02% (200 ppm). For higher concentration operations, the capacity of the engine or auxiliary power unit must be demonstrated. For example, for an aircraft whose auxiliary power unit can only be activated on the ground, the justifications vis-à-vis the certification regulations are simpler, and the criticality linked to a failure of the auxiliary power unit is less big.
    In addition, the auxiliary power unit is able to operate even when the aircraft engines are off. The purge can therefore be implemented both on the ground and in flight and in particular when the aircraft is stationary.
    The purge system 22 and the energy production device 12 are then configured in particular so that, for at least one flow rate in the supply line 20, the water concentration of the fuel 24 flowing in the supply line 20 is greater than 1%, preferably greater than 1.5%.
    Advantageously, the minimum dilution rate is greater than 0.7 L / min, for example equal to 1 L / min.
    In addition not illustrated to the second set 10B, as for the previously described complement to the first set 10A illustrated in FIG. 7, the second set 10B similarly comprises at least one additional tank 200, a system for purging the water contained in the additional tank 200, a control valve 206 associated with each supply line 20 and a processing unit 208.
    At least one region of the transport line 44 comprising the ejection outlet 54 is coaxial with a region of the supply line 20 comprising the open end 38 and the reception region 42 of the supply line 20.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    1Airplane power generation package including:
    - an energy production device (12);
    - a pump (14);
    - at least one tank (16) containing fuel, the tank (16) comprising a fuel supply line (20); and
    - at least one purge system (22) of the water contained in the tank (16), the purge system (22) comprising:
    • a transport line (44) fluidly connected to the supply line (20), the transport line (44) having at least one fuel suction inlet (52) opening into the tank (16) and a venturi (62) downstream of the fuel suction inlet (52); and • a sample line (46), integral with the transport line (44), extending between a sample inlet (110) and a sample outlet (112), the sample inlet (110) opening into a region (36) of the reservoir (16) suitable for accumulating water, the sampling outlet (112) opening into the transport pipe (44), upstream or into the venturi (62);
    characterized in that the pump (14) is arranged downstream of the venturi, and at least one region of the sampling line (46) comprising the sampling outlet (112) is coaxial with the transport line (44).
    [2" id="c-fr-0002]
    2, - assembly according to claim 1, wherein the energy production device (12) is an auxiliary power unit, the supply line (20) being intended to supply said auxiliary power unit (12) with the fuel contained in said tank (16), the supply line (20) being connected to the auxiliary power unit (12) and connected to the pump (14).
    [3" id="c-fr-0003]
    3. - The assembly of claim 2, wherein the energy production device (12) is configured so that the nominal flow rate in the supply line (20) is less than 2 L / min.
    [4" id="c-fr-0004]
    4, - An assembly according to any one of claims 1 to 3, wherein the transport line (44) extends to a free end, the sampling line (46) being received in the transport line (44 ) through the free end of the transport line (44).
    [5" id="c-fr-0005]
    5. - An assembly according to any one of claims 1 to 4, wherein the sampling line (46) extends until it is in contact with an inner surface (28) of a wall (18) of the reservoir ( 16), the sampling inlet (110) being defined by a lateral opening (114), the lateral opening (114) preferably having an open contour.
    [6" id="c-fr-0006]
    6. - Assembly according to any one of claims 1 to 5, wherein the transport pipe (44) comprises a retaining neck (250) of the sampling pipe (46), the retaining neck (250) enclosing the sampling line (46).
    [7" id="c-fr-0007]
    7. - An assembly according to claim 6, wherein the transport line (44) comprises a suction cone (254) upstream of the venturi (62), the suction inlet (52) of the transport line ( 44) being delimited between the retaining neck (250) and the suction cone (254).
    [8" id="c-fr-0008]
    8. - An assembly according to any one of claims 6 or 7, comprising a positioning block (256) of the sampling line (46), the sampling line (46) comprising a positioning projection (258), the block positioning (256) being interposed between the positioning projection (258) and the retaining neck (250) and being in contact with the positioning projection (258) and the retaining neck (250).
    [9" id="c-fr-0009]
    9. - Assembly according to any one of claims 1 to 8, in which the supply line (20) is directly connected to the energy production device (12) without intermediate reservoir between the two.
    [10" id="c-fr-0010]
    10. - assembly according to any one of claims 1 to 9, comprising at least one additional tank (200) and an additional purge system (202) of the water contained in the additional tank (200), the assembly comprising furthermore a control valve (206) associated with each supply line (20, 203), each control valve (206) having an opening configuration and a closing configuration of the supply line (20, 203 ) with which it is associated.
    [11" id="c-fr-0011]
    11. - assembly according to claim 10, further comprising a processing unit (208) configured to successively open each control valve (206) for a predetermined period of time, the processing unit (208) being configured for n ' authorizing the opening of only one of said control valves (206) per predetermined period of time.
    [12" id="c-fr-0012]
    12. - Method for purging the water contained in an aircraft fuel tank (16), comprising the steps of:
    - supply of an assembly according to any one of claims 1 to 11;
    - actuation of the pump (14); and
    - purging by suction of the water contained in the tank (16), this step of purging by suction comprising the sub-steps of:
    - suction of fuel through the suction inlet (52) of the transport pipe (44), and flow of the fuel sucked towards the energy production device (12) via the supply pipe ( 20); and
    - Suction of water through the sampling inlet (110) of the sampling pipe (46), and flow of the sucked water towards the energy production device (12) via the pipe d power supply (20).
    [13" id="c-fr-0013]
    13. - The method of claim 12, wherein, during the water suction step, the pressure difference between the suction inlet (52) and the sampling inlet (110) is equal to the difference in hydrostatic pressure between the suction inlet (52) and the sampling inlet (110).
    [14" id="c-fr-0014]
    14. - Method according to any one of claims 12 or 13, wherein the sub-step of suction of water by the sampling inlet (110) is implemented only when the flow rate in the supply line (20) is greater than a minimum dilution flow, the minimum dilution flow being greater than 110% of a minimum operating flow that the energy production device (12) is capable of imposing in the supply line (20).
    [15" id="c-fr-0015]
    15. - Method according to any one of claims 12 to 14, wherein the assembly comprises at least one additional tank (200) and an additional purge system (202) of the water contained in the additional tank (200) ; the assembly further comprising a control valve (206) associated with each supply line (20, 203), each control valve (206) having an opening configuration and a closing configuration of the supply line (20, 203) with which it is associated;
    the method successively comprising purging by suction of the water contained in each tank (16, 200) by successively opening each control valve (206) for a predetermined period of time, only one of said control valves (206) being opened by predetermined period of time.
    类似技术:
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    同族专利:
    公开号 | 公开日
    FR3084056B1|2020-10-09|
    CA3049216A1|2020-01-17|
    US20200023291A1|2020-01-23|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0278755A2|1987-02-12|1988-08-17|British Aerospace Public Limited Company|On-board disposal of water in aircraft fuel tanks|
    WO2008059288A1|2006-11-13|2008-05-22|Airbus Uk Limited|Water scavenging system|
    WO2008059287A1|2006-11-13|2008-05-22|Airbus Uk Limited|Water scavenging system|
    EP3272654A1|2016-07-20|2018-01-24|Airbus Operations Limited|Removing water from fuel tanks|
    US10773819B2|2017-08-21|2020-09-15|Hamilton Sunstrand Corporation|Fuel tank with water bladder|
    FR3084055B1|2018-07-17|2020-10-02|Dassault Aviat|SYSTEM AND KIT FOR PURGING A TANK AND ASSOCIATED PURGE AND ASSEMBLY METHODS|
    法律状态:
    2019-06-24| PLFP| Fee payment|Year of fee payment: 2 |
    2020-01-24| PLSC| Publication of the preliminary search report|Effective date: 20200124 |
    2020-06-17| PLFP| Fee payment|Year of fee payment: 3 |
    2021-06-11| PLFP| Fee payment|Year of fee payment: 4 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1800764|2018-07-17|
    FR1800764A|FR3084056B1|2018-07-17|2018-07-17|ENERGY PRODUCTION UNIT AND PROCESS FOR PURGING THE WATER CONTAINED IN AN ASSOCIATED AIRCRAFT TANK|FR1800764A| FR3084056B1|2018-07-17|2018-07-17|ENERGY PRODUCTION UNIT AND PROCESS FOR PURGING THE WATER CONTAINED IN AN ASSOCIATED AIRCRAFT TANK|
    CA3049216A| CA3049216A1|2018-07-17|2019-07-10|Energy production assembly and associated process for draining water contained in an aircraft fuel tank|
    US16/513,810| US20200023291A1|2018-07-17|2019-07-17|Energy production assembly and method for purging water contained in an associated aircraft tank|
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