• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Systems and methods for improving engine performance based on atmospheric precipitation conditions are provided. For example, a method may include selecting one or more points (420) on a flight path (410) of an aircraft (102) and receiving a radar reflectivity measurement for the point / each of the points (420), obtained by means of a radar device placed on the aircraft (102). The method may further include determining a liquid water presence estimate for the point / each of the points (420) at least partially from the radar reflectivity measurements; and controlling at least one part of the aircraft engine (eg a variable pitch stator blade) at least partially according to the liquid water presence estimate for at least one point of the plurality of points (420).
    公开号:FR3043140A1
    申请号:FR1660160
    申请日:2016-10-20
    公开日:2017-05-05
    发明作者:Nicholas Race Visser;Sridhar Adibhatla;David Michael Lax
    申请人:GE Aviation Systems LLC;
    IPC主号:
    专利说明:

    IMPROVING ENGINE PERFORMANCE TO REDUCE FUEL CONSUMPTION ACCORDING TO ATMOSPHERIC PRECIPITATION CONDITIONS
    The present invention relates generally to improving the performance of aircraft engines.
    An aircraft may include an engine such as a gas turbine engine for the propulsion of the aircraft. A gas turbine engine may include a blower and a gas generator in flow communication with each other. The gas turbine engine gas generator generally comprises an air flow path having, in series on the air flow path, a compressor section, a combustion section, a turbine section and an exhaust section. The compressor section may include one or more compressors for compressing air. The compressed air can be supplied to the combustion section where it is mixed with fuel and burned to produce flue gases. The combustion gases can be used to operate the compressor section and turbine section of the gas turbine engine.
    In flight, an aircraft may encounter liquid water in the form of rain on its flight path. This usually happens at altitudes where the aircraft is in the takeoff, climb or descent phase. The large amounts of liquid water ingested by an aircraft engine can be problematic, as energy is expended to convert water into steam during the combustion process. This can cause an increase in the specific fuel consumption by the engine during the ascent and descent when rain is present in the flight path of the aircraft.
    For example, the aircraft engine may have parts associated with the geometry of the airflow, located in the path of the air flow in the gas generator to act on various aspects of the combustion process. For example, stator vanes can be used to alter the flow of air flowing to the compression and combustion sections of the gas turbine engine. Staggered stator vanes can be controlled, for example, using temperature sensors located at different locations in the engine. Controlling the variable-pitch stator vanes using temperature sensors may not adequately compensate for the presence of atmospheric liquid water ingested by the aircraft engine. For example, variable-pitch stator vanes can be controlled using temperature sensors to be more closed than they should be during the presence of atmospheric precipitation conditions, causing an increase in fuel consumption. fuel.
    Aspects and advantages of embodiments of the present invention will be partially set forth in the description below, or may be learned from the description, or may be apparent from the practice of the embodiments.
    A first exemplary aspect of the present invention relates to an aircraft engine control method. The method includes identifying, by one or more computing devices, one or more points on a flight path of an aircraft. The method further comprises receiving, by the computer device (s), a reflectivity measurement for the point / each of the points, obtained using a device placed on the aircraft. The method further comprises determining, by the computing device (s), an estimate of the presence of liquid water for the point / each of the points, at least partially according to the reflectivity measurement for the point; and controlling, by the computer device (s), at least one part of the aircraft engine at least partially according to the estimate of the presence of liquid water for the point (s). Other exemplary aspects relate to control systems, devices, aircraft, apparatuses and other systems designed to control at least one part of an engine at least partially according to the estimate of the presence of water liquid. Variations and modifications can be made to these exemplary aspects of the present invention.
    These features, aspects and advantages of various embodiments will become more apparent with reference to the following description and the appended claims. The accompanying drawings, which form an integral part of this specification, illustrate embodiments of the present invention and, together with the description, serve to explain the related principles. The invention will be better understood from the detailed study of some embodiments taken by way of nonlimiting examples and illustrated by the appended drawings in which: FIG. 1 represents a general view of an exemplary system according to examples embodiments of the present invention; Fig. 2 shows an example of a computing device used in a control system according to exemplary embodiments of the present invention; Figure 3 shows a flowchart of an exemplary method according to exemplary embodiments of the present invention; FIG. 4 illustrates the example of determining the presence of liquid water for a plurality of points by means of reflectivity measurements according to exemplary embodiments of the present invention; and FIG. 5 shows an exemplary flowchart of an exemplary liquid water presence estimation algorithm according to exemplary embodiments of the present invention.
    Embodiments of the invention will now be discussed in detail, of which one or more examples are illustrated in the drawings. Each example is presented as an explanation of the invention, without limiting the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the scope and spirit of the invention. For example, details illustrated or described in connection with one embodiment may be used with another embodiment to provide yet another embodiment. Thus, the present invention covers these modifications and variations as being within the scope of the appended claims and their equivalents.
    Examples of aspects of the present invention relate to systems and methods for improving engine performance by detecting atmospheric precipitation conditions. More particularly, liquid water in the form of rain on the flight path of the aircraft can be detected by means of reflectivity measurements obtained by a device (eg a radar device) placed on the aircraft. aircraft. An algorithm for estimating the presence of liquid water can be used to estimate the presence of liquid water (eg in units such as grams per cubic meter, g / m3) based on reflectivity measurements for points on the flight path of the aircraft. One or more pieces (e.g. statically variable stator vanes) of the aircraft engine can be controlled at least partially according to the estimate of the presence of liquid water in order to improve the fuel flow of the aircraft under conditions of atmospheric precipitation such as rain conditions encountered during takeoff, ascent and descent of the aircraft. The estimation of the presence of liquid water may be particularly applicable to ambient temperatures where rainfall conditions may be encountered. The highest altitude at which rainfall occurs may be an altitude at which the ambient temperature becomes 0 ° C. Exemplary aspects of the present invention may utilize ambient temperature data (eg collected by an ambient temperature sensor associated with the aircraft or other data) to determine when to operate the aircraft. system in liquid water presence detection mode. For example, the aircraft may make an estimate of the presence of liquid water in liquid water presence detection mode according to exemplary aspects of the present invention when the ambient temperature exceeds 0 ° C or another threshold.
    When a liquid water presence estimation mode is initiated, the systems and methods according to exemplary aspects of the present invention can estimate, based on reflectivity measurements, the presence of liquid water for points on the path. flight of the aircraft. More particularly, points that the aircraft must meet within a given time on the flight path (eg points through which the aircraft must pass in the next minute) can be identified at a particular resolution. Reflectivity measurements can be obtained for the identified points.
    An estimate of the presence of liquid water for each of the identified points can be determined from the reflectivity measurements using an algorithm for estimating the presence of liquid water. For example, parameters for a drop size distribution model can be determined and used to estimate the presence of liquid water based on the reflectivity measurement for the point.
    In some embodiments, a plurality of estimated values for each point may be obtained as the aircraft traverses the flight path. Each estimated value can be associated with a particular reflectivity measurement. The liquid water presence estimate may be refined as the aircraft travels the flight path from the plurality of estimated values using a weighted averaging function. The weighted averaging function may assign greater weight to estimated values associated with reflectivity measurements for points closer to the aircraft, since reflectivity measurements are usually more accurate. In this way, the estimate of the presence of liquid water can be continuously improved as the aircraft approaches the point.
    Once the estimate of the presence of liquid water for a point is obtained, the estimate can be used to control one or more parts associated with the aircraft engine, for example, to improve fuel consumption. combustible. For example, one or more parts associated with the geometry of the air flow (eg inlet guide vanes, stator vanes with variable timing, etc.) can be controlled ( s) to regulate the level of pressure in the aircraft engine in order to improve fuel economy.
    In particular embodiments, the variable-pitch stator vanes can be controlled from the liquid water presence estimate. For example, variable-pitch stator vane position settings specified by nominal specifications can be made, at least partially based on the liquid water presence estimate to regulate the flow of air into the chamber. aircraft engine. In one embodiment, the variable-pitch stator vanes can be controlled to be further open relative to a specified position by nominal specifications when the liquid water presence estimate exceeds a threshold.
    In this way, examples of aspects of the present invention may have the technical effect of ensuring an improvement in the performance of an aircraft engine when the aircraft encounters atmospheric precipitation on the flight path of the aircraft. Ensuring a more efficient control of an aircraft engine (eg more efficient control of variable valve stator blades) based on estimates of liquid water presence can result in more efficient fuel consumption potentially driving fuel savings for the operation of the aircraft. In addition, the estimation of the presence of liquid water according to exemplary aspects of the present invention can be carried out by means of devices (eg radar devices) placed on many types of different aircraft, so it can lend itself to all kinds of applications to help improve the performance of aircraft engines.
    Figure 1 illustrates an exemplary system 100 for controlling one or more parts of an aircraft engine to improve engine performance according to exemplary aspects of the present invention. As shown, the system 100 may include a control system having one or more computer device (s) 200 (eg, a computer-based control system) or other associated control equipment, for example, an avionics system of the aircraft 102. The computer device (s) 200 can be coupled to various systems of the aircraft 102 via a communication network 140. The communication network 140 can include a data bus and / or combination of wired and / or radio communication links.
    The system 100 may include a radar device 112 associated with the aircraft 102. The radar device 112 may be designed to obtain radar reflectivity measurements. The radar device 112 may emit a radar beam 114 (eg, radio waves) and measure the reflectivity of the radar beam 114 reflected by objects (eg, liquid water particles) located on the flight path. of the aircraft 102. The radar device 112 may emit a radar beam 114 having a radar beam width W as shown in FIG. 1. The radar device 112 may obtain reflectivity measurements in dBZ (e.g. in decibels with respect to Z). These reflectivity measurements can compare the equivalent reflectivity (Z) of a radar signal with the return of a rain droplet of 1 mm in diameter. In some embodiments, the radar device 112 may be associated with an on-board weather system 110 for the aircraft 102. In some embodiments, the radar device 112 may be an X-band radar device (e.g. associated with a frequency range of 7.0 to 11.2 Gigahertz (GHz)). For illustrative and explanatory purposes, the present invention is set forth with reference to performing reflectivity measurements using a radar device on the aircraft. Those of ordinary skill in the art will appreciate, using the explanations provided herein, that other types of devices can be used to obtain the reflectivity measurements. For example, a lidar device or other reflectivity-based technology may be used to obtain the reflectivity measurements.
    The system 100 may further include a temperature sensor 116 associated with the aircraft 102. The temperature sensor 116 may measure the ambient temperature around the aircraft 102 while the aircraft is in flight. In the same way as the radar device 112, the ambient temperature sensor 116 may be associated with the onboard weather system 110 for the aircraft 102.
    According to exemplary embodiments of the present invention, the computer device (s) 200 can access data from the on-board weather system 110 (e.g. radar reflectivity measurements and ambient temperature data) and use the data to control one or more parts of the aircraft to save more fuel. More particularly, the computer device (s) 200 can / can control parts associated with aircraft engines 104, used to propel the aircraft 102, in order to save more fuel according to data extracted from the onboard weather system 110.
    More particularly, as illustrated in FIG. 1, the computer device (s) 200 can communicate with control systems 120 of engines associated with aircraft engines 104. Aircraft engines 104 may be, for example, gas turbine engines. The motor control systems 120 may be designed to control parts of the aircraft engines 104 in response to instructions provided by the computer device (s) 200. For example, the engine control system 120 can adjust parts associated with airflow geometry of aircraft engines 104 (e.g., stationary vanes in the airflow path of aircraft engines 104) from instructions from / computer device (s) 200. In one embodiment, the motor control systems 120 can, from instructions from the computer device (s) 200, control stator vanes to variable timing associated with aircraft engines 104 to be more open or less closed. The instructions from the computer device (s) 200 can be determined at least partially from the radar reflectivity measurements obtained by the radar device 112, as explained in more detail below.
    In some embodiments, the computer device (s) 200 may communicate with other on-board systems via the communication network 140. The on-board systems may include, for example, a computer system. display 130 comprising one or more display devices that can be designed to display or otherwise present to the operators of the aircraft 102 information generated or received by the system 100. The display system 130 may include a main flight screen, a multifunction control display unit or another suitable flight screen commonly present in a cabin of the aircraft 102. By way of non-limiting example, the display system 130 may be used to display flight information such as the aircraft's own speed, altitude, attitude and azimuth 102.
    The computer device (s) can also communicate with a flight control computer 132. The flight control computer 132 can, among other things, automate the tasks of piloting and tracking the flight plan. of the aircraft 102. The flight control computer 132 may include or be associated with any number of individual members such as microprocessors, power sources, storage devices, interface cards, autopilots, flight management computers and other conventional devices. The flight control computer 132 can understand or cooperate with any number of software (eg flight management programs) or instructions designed to implement the various processes, process tasks, calculations. and control / display functions necessary for the operation of the aircraft 102. The flight control computer 132 is illustrated as being separate from the computer device (s) 200. Those skilled in the art, using the present invention, will understand that the flight control computer 132 may also be included in the computer device (s) 200 or be implemented by them.
    The computer device (s) 200 may also communicate with various other onboard systems 134. The shipboard systems 134 may include, for example, digital control systems, throttle control systems, inertial platforms reference systems, flight instrument systems, auxiliary groups, fuel control systems, aircraft vibration control systems, communication systems, flap control systems, flight data and other systems.
    Figure 2 shows various components of the computer device (s) 200 according to exemplary embodiments of the present invention. As shown, the computing device (s) 200 may / may include one or more processor (s) 212 and one or more memory device (s) 214. The processor (s) 212 may may include any suitable processing device such as a microprocessor, a microcontroller, an integrated circuit, a logic device or other suitable processing device. The memory device (s) 214 may / may comprise one or more computer-readable medium (s), including, in a non-limiting manner, non-transitory computer-readable mediums, random access memories, memory sticks, hard disk drives, flash memory keys or other memory devices.
    The memory device (s) 214 may / may store information accessible to the processor (s) 212, including computer-readable instructions 216 that may be executed by the processor (s) 212. The instructions 216 may be any set of instructions that, when executed by the processor (s) 212, cause the processor (s) 212 to perform operations. The instructions 216 may be any set of instructions that, when executed by the processor (s) 212, cause the processor (s) 212 to perform operations. The instructions 216 may be implemented by software written in any suitable programming language or may be implemented in hardware. In some embodiments, the instructions 216 may be executed by the processor (s) 212 to cause the processor (s) to perform operations such as operations to determine the presence of liquid water and to control one or more several parts of an aircraft engine, as described with reference to Figure 3.
    Referring to Figure 2, the memory devices 214 may further store data 218 accessible to the processors 212. The data 218 may include, for example, radar reflectivity data, ambient temperature measurements, water presence estimates. liquid and other data. The data 218 may also include data associated with models and algorithms for performing the exemplary methods according to exemplary aspects of the present invention, such as drop size distribution models and algorithms for estimating the presence of liquid water.
    The computer device (s) 200 may / may further comprise a communication interface 220. The communication interface 220 may be designed to communicate with on-board systems via a communication network such as the communication network. For example, the communication interface 220 may receive, from an onboard weather system 110, radar reflectivity measurements and ambient temperature measurements. The communication interface 220 may provide control instructions to the motor control systems 120. The communication interface 220 may include any suitable organs for interfacing with one or more other devices including, for example, transmitters, receivers, ports, controllers, antennas or other suitable organs.
    The technology explained here provides computer-based systems, as well as actions taken and information sent to and from these systems. It will be understood by one of ordinary skill in the art that the flexibility inherent in computer-based systems allows a wide variety of possibilities for configurations, combinations and distribution of tasks and functions between and among organs. For example, the processes discussed herein may be implemented using a single computing device or multiple computing devices cooperating with each other. Databases, memory, instructions, and applications can be implemented on a single system or distributed across multiple systems. The distributed members can operate in series or in parallel.
    Fig. 3 is a flowchart of an exemplary method (300) according to exemplary embodiments of the present invention. The method (300) can be implemented using one or more computer device (s) such as the computer device (s) 200 of FIGS. 1 and 2. method or parts of the method may / may be implemented at least partially by other devices such as processors associated with the radar device 112 or with one or more other device (s) without departing from the scope of the present invention. In addition, Figure 3 presents, for purposes of illustration and explanation, steps performed in a particular order. It will be understood by those of ordinary skill in the art utilizing the present invention that various steps of any of the methods set forth herein may be modified, rearranged, omitted, developed and / or adapted in a variety of ways without departing from the scope of the present invention.
    In (302), the method comprises obtaining a measurement of ambient temperature using an ambient temperature sensor. For example, an ambient temperature measurement provided by the ambient temperature sensor 116 installed on the aircraft 102 may be accessible. The ambient temperature measurement can be obtained from other suitable sources without departing from the scope of the present invention. For example, the ambient temperature measurement may be based on data stored in an onboard weather system for the aircraft.
    In (304), the method determines whether or not it is necessary to start the liquid water presence detection mode according to the ambient temperature measurement. For example, if the measured ambient temperature exceeds a threshold of ambient temperature, the method may include the launching of the liquid water presence detection mode in order to control the aircraft as a function of the presence of detected liquid water, as explained more in detail below. Otherwise, the process may continue to control the ambient temperature until the measured ambient temperature exceeds the ambient temperature threshold.
    As explained above, an aircraft is likely to encounter liquid water in the atmosphere at an altitude where the ambient temperature is 0 ° C. Thus, in one embodiment, the method may include initiating the LWC detection mode if the measured ambient temperature is greater than 0 ° C. Other suitable thresholds may be used without departing from the scope of the present invention. For example, the threshold may be about 10 ° C, 5 ° C, 2.5 ° C or other suitable value without departing from the scope of the present invention. For the purpose of this description, the use of the term "about" assigned to a numerical value is intended to evoke a margin of 30% with respect to the numerical value.
    When the detection mode of presence of liquid water is launched, the method may include the identification of one or more points on the flight path of the aircraft, as indicated in (306) in Figure 3. More particularly , on the current flight path, one or more points (eg each associated with a latitude / longitude / altitude) may / may be selected on the flight path of the aircraft to an arbitrary resolution value. The resolution value may be an indication of the number of points and / or the spacing of the points to be identified on the flight path.
    The points identified may be within the radar beamwidth associated with the radar device equipped with the aircraft. The points may be chosen in an interval corresponding to a period of time during which the minimum is associated with the nearest point for which a radar reflectivity measurement can be obtained and the maximum is a point which is considered to be the aircraft encounter it at a given point in time on the flight path (eg the aircraft will encounter within 1 minute on the flight path) provided that the point is within the beam width radar.
    For example, Figure 4 shows a plurality of identified points 420 on a flight path 410. The plurality of points 420 is represented as points on the curve corresponding to the flight path 410. Each of the points 420 may be associated with a latitude / longitude / altitude. The resolution of the dots 420 can be identified according to any appropriate resolution value. The points 420 may lie within the limits of the radar beam width W associated with the radar beam 114 emitted by the radar device 112 with which the aircraft 102 is equipped. For example, the point 422 on the flight path is beyond the width limits W of the radar beam 114 emitted by the radar device 112 of which the aircraft is equipped and, in some embodiments, is not identified to be included in the plurality of points.
    Referring to Figure 3, in (308) the method may include receiving radar reflectivity measurements for the point / each of the points on the flight path of the aircraft. For example, a radar reflectivity measurement (eg in dBZ) can be obtained for each of the points 420 on the flight path 410 of the aircraft 102.
    In (310) of Figure 3, the method includes determining a liquid water presence estimate for the at least one point (s) based on radar reflectivity measurements for the points. The liquid water presence estimate may also be based on other data, including reflectivity measurements obtained from other sources (eg other aircraft) and / or meteorological data obtained from a data source. meteorological service. In an exemplary embodiment, the radar reflectivity metering for each point can be provided to a liquid water presence estimation algorithm that can generate a value estimate for the point. Details about an example of liquid water presence estimation algorithm will be discussed later with reference to Figure 5.
    In a particular example of implementation, the determination of the presence of liquid water for each of the points of the plurality of points can be carried out continuously to give a table, on the influence of the trajectory, the presence of liquid water in the air mass at the front of the aircraft. For example, a set of estimated values for the point / each of the points can be obtained as the aircraft traverses the flight path. Each estimated value can be associated with a particular radar reflectivity metric for the point and can be determined using the liquid water presence estimation algorithm. It can construct a set of estimated values for the point on the flight path, with the nearest point having most of the estimated values and the farthest point having only one value.
    For example, as shown in FIG. 4, the nearest point 420.1 may have estimated values LWCi, LWC2, ... LWCn of presence of liquid water. The next nearest point 420.2 may have an estimated value of less than the nearest point 420.1. More particularly, the next nearest point 420.2 may have estimated values of liquid water presence LWCi, LWC2, ... LWCn-i. The next nearest point 420.3 may have an estimated value of less than the nearest point 420.2. More particularly, the next nearest point 420.3 may have LWCi, LWC2, LWCn-2 estimated liquid water values. The next nearest point may have an estimated value of less than the nearest point 420.3, and so on. The farthest point 420.n can have a single estimated value LWCi.
    For each point, a weighted average setting function can be applied to the estimated values to determine the liquid water presence estimate for the point. For example, as shown in Fig. 4, the estimated values LWCi, LWC2, ... LWCn can be provided to a weighted averaging function 430 to determine an LWCe estimate of liquid water presence for 420.1 . The weighted averaging function 430 can assign the greatest weight to estimated values associated with the most accurate radar reflectivity measurements. For example, the weighted averaging function 430 may assign the greatest weight to estimated values for given radar reflectivity measurements obtained for points closest to the aircraft.
    Considering Figure 3 in (312), the method may include controlling at least one part of the aircraft engine at least partially according to the liquid water presence estimate for the points. For example, in one embodiment, parts associated with the airfoil geometry of the aircraft engine (e.g., inlet guide vanes, stator vanes with variable timing, etc.) can be adjusted. from the liquid water presence estimate to adjust the airflow pressure in the aircraft engine to cope with the presence of liquid water in the airflow path and improve fuel consumption fuel. By way of example, variable-pitch stator vanes associated with the aircraft engine may be set to be more open or closed than normally specified, for example, by a nominal specification at least partially based on the presence estimate of the engine. liquid water. For example, if the liquid water presence estimate exceeds a threshold, the variable pitch stator vanes can be controlled to be more open than normally specified by a nominal variable stator vane position specification.
    Fig. 5 is a flowchart of an exemplary estimation algorithm (500) for the presence of liquid water according to exemplary embodiments of the present invention. The liquid water presence estimation algorithm can determine the presence of liquid water based on radar reflectivity measurements using a droplet size distribution model for water droplets.
    In (502), the method may include access to a drop size distribution model. More particularly, as shown in FIG. 5, the radar reflectivity may be proportional to the sum of the sixth powers of the diameter of the water droplets. In this way, a drop size distribution model can be defined in the following manner according to the radar reflectivity:
    where Z is the radar reflectivity measure, D is the drop size distribution, N is the number of droplets, Λ is a first parameter associated with the model, μ is a second parameter associated with the model, and Γ is the gamma function associated with the model. the size distribution of drops. Based on a better approximation of the N value at 50,000 and a relationship between μ and A, the parameters for the model can be solved using the following system of equations:
    where Zmeasured is the reflectivity measure and Cl, C2 and C3 are constants associated with the relation between μ and Λ.
    In (504), a value for a first parameter Λ is determined using the system of equations above from an initial approximation of μ. In (506), a value for a second parameter μ is calculated using the value determined for the first parameter Λ. The first parameter Λ is then recalculated to (508) using the value determined for the second parameter μ.
    In (510), it is determined whether, or not, the difference in value between the first calculated parameter Λ and the value previously calculated for the first parameter Λ is below a tolerance. If not, the parameters are redetermined according to (506) and (508). If yes, the process continues until (512) where the water presence estimate is determined from the drop size distribution model. For example, from the resolved parameters, the algorithm can calculate the presence of liquid water according to the third moment of the distribution. More particularly, the presence of liquid water can be calculated as follows:
    where p is the density of the drops (eg measured in g / m3), which can be assumed to be 1000 g / m3.
    Although specific details of various embodiments may be shown in some drawings and not others, it is only for convenience. According to the principles of the present invention, any detail of a drawing may be cited and / or claimed in combination with any detail of any other drawing.
    LIST OF REFERENCES
    Number Designation 100 System 102 Aircraft 104 Aircraft engine 110 On-board weather system 112 114 Radar device 116 Radar beam 120 Temperature sensor 130 132 engine control system 134 Display system 140 Flight control computer 200 Systems 212 Communication network 214 Computer device (s) 216 Processor (s) 218 Memory device (s) 300 Instructions 302 Data 304 Method 306 Process step 308 Process step 310 Process step 312 Step 410 Process Step 420 Process Step 420.n Flight Path 420μ.1 Points 420.2 Farthest Point 420.3 Nearest Point 422 Next Closest Point 430 Next Closest Point
    Item 500 Weighted Average Setting Function 502 Liquid Water 504 Estimation Algorithm 506 Process Step 508 Process Step 510 Process Step 512 Process Step
    Process step Process step
    权利要求:
    Claims (10)
    [1" id="c-fr-0001]
    A method of controlling an aircraft engine (104), comprising: identifying, by one or more processor (s) (212), one or more point (s) (420) on a flight path (410) an aircraft (102); the access of the processor (s) (212) to a reflectivity measurement for the point / each point (420), the reflectivity measurement being obtained from a device disposed on the aircraft (102); determining, by the processor (s) (212), an estimate of the presence of liquid water for the point / each of the points (420) at least partially according to the reflectivity measurement for the point; and controlling, by the processor (s) (212), at least one part of the aircraft engine (104) at least partially according to the liquid water presence estimate for the point (s) (s) (420).
    [2" id="c-fr-0002]
    2. The method of claim 1, wherein the part (s) comprises / comprise a part associated with an air flow geometry of the aircraft engine (104).
    [3" id="c-fr-0003]
    3. The method of claim 2, wherein the part associated with the air flow geometry of the aircraft engine (104) comprises one or more stator (s) statically variable blade (s) of the engine (104) d. 'aircraft.
    [4" id="c-fr-0004]
    The method of claim 1, wherein the reflectivity measurement for the point / each of the points (420) comprises a radar reflectivity measurement obtained from a radar device (112).
    [5" id="c-fr-0005]
    5. Method according to claim 1, wherein the liquid water presence estimate is made from the radar reflectivity measurement using an estimation algorithm (500) for the presence of liquid water, the liquid water presence estimating algorithm (500) comprising: estimating, by the processor (s) (212), one or more parameters for a drop size distribution pattern at the less partially from radar reflectivity measurement; and determining, by the processor (s) (212), the estimate of the presence of liquid water at least partially from the parameters for the drop size distribution model.
    [6" id="c-fr-0006]
    The method of claim 1, wherein determining a liquid water presence estimate for the point / each of the points (420) comprises: determining, by the processor (s) (212), a set of estimated values for the point / each of the points (420) as the aircraft (102) traverses the flight path (410), each estimated value in the set of estimated values being associated with a given measurement radar reflectivity for the point; and determining, by the processor (s) (212), the liquid water presence estimate at least partially from the set of estimated values.
    [7" id="c-fr-0007]
    The method of claim 6, wherein the liquid water presence estimate is determined at least partially from the set of estimated values using a weighted average setting function (430). , the weighted averaging function (430) assigning greater weight to estimated values associated with given radar reflectivity metrics obtained for the points (420) closest to the aircraft (102).
    [8" id="c-fr-0008]
    8. The method of claim 1, wherein the control, by the processor (s) (212), of at least one part of the aircraft engine (104) at least partially according to the estimate of presence. liquid water is performed when the aircraft (102) operates in liquid water presence detection mode.
    [9" id="c-fr-0009]
    9. The method of claim 8, the method comprising: obtaining, by the processor (s) (212), a measurement of ambient temperature using a temperature sensor; and activating, by the processor (s) (212), the mode of detecting the presence of liquid water at least partially according to the ambient temperature.
    [10" id="c-fr-0010]
    A system for controlling an engine (104) of an aircraft (102), comprising: a radar device (112) located on the aircraft (102), the radar device (112) being adapted to obtain radar reflectivity for a volume of air within the width of a radar beam (114) associated with the radar device (112); a control system comprising one or more processor (s) (212) and one or more memory device (s) (214), the memory device (s) (214) storing instructions (216) computer-operable, which, when executed by the processor (s) (212), causes the processor (s) (212) to perform operations, the operations comprising: identifying a plurality of points (420) on a flight path (410) of an aircraft (102); accessing a radar reflectivity measurement for each point of the plurality of points (420), obtained using the radar device (112) for determining an estimate of the presence of liquid water for each point of the plurality of points (420) at least partially according to the radar reflectivity measurement for the point (420); and controlling at least one part of the aircraft engine (104) at least partially according to the liquid water presence estimate for at least one of the plurality of points (420).
    类似技术:
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    优先权:
    申请号 | 申请日 | 专利标题
    US14/927709|2015-10-30|
    US14/927,709|US9938017B2|2015-10-30|2015-10-30|Enhancing engine performance to improve fuel consumption based on atmospheric rain conditions|
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