HIGH ACCURACY FUEL SYSTEM

Abstract

A fuel device including a housing having at least one fuel channel configured to direct, meter, sense or pump fuel there through, and a characterization device coupled to the housing including a memory chip, wherein the memory chip includes measured performance data of the fuel channel.

Description

BACKGROUND

Technological Field

This disclosure relates to a fuel system, and particularly to an improvement of the calibration and metering flow accuracy of the fuel system.

Description of Related Art

A gas turbine engine's performance heavily depends on the ability of a fuel system to meter flow accurately. Fuel system mass flow accuracy depends on the difference between calculated flow and actual metered flow.

The nominal relationship of a device's metering valve position to mass flow is stored on Electronic Engine Controller (EEC). System accuracy thus depends on the metering valve position sensor accuracy, metering window manufacturing tolerances, the accuracy of the pressure regulating valve and uncertainty of specific gravity of the fuel. Today's typical fuel system accuracies generally fall in the 3-6% range, causing uncertainty in the actual fuel delivered to the engine. Uncertainty results in engines being operated at less than optimal performance.

Typical systems also require a mechanical calibration of each individual pump, sensor or metering valve, which meter flow based on mechanical position, as opposed to actual flow. Although the conventional methods and systems have generally been considered satisfactory for their intended purpose, a means of improving metered flow accuracy across the fuel system is desired. There also remains a need in the art for such metering and components that are economically viable. The present disclosure provides an improvement with respect to at least these challenges.

SUMMARY OF THE INVENTION

A fuel device includes a housing including at least one fuel channel configured to accept or pass fuel there through, and a characterization device coupled to the housing including a memory chip, wherein the memory chip includes measured performance data of the at least one fuel channel. The at least one fuel channel can include a metering valve or a pressure regulating valve or a pump or a sensor. The fuel device can be for example a fuel metering unit, a fuel pump, a densimeter and a flow divider valve.

The characterization device can include a communication device configured to passing measured performance data to an electronic engine controller. The measured performance data can include a plurality of fuel pressure, fuel density, fuel temperature conditions. The measured performance data can also include internal fuel leakage rates.

A fuel system includes at least one fuel device for directing, metering, sensing or pumping fuel as part of a gas turbine engine, comprising a characterization device configured to store measured performance data of the device and communicate the performance data to an electronic engine controller, and an electronic engine controller coupled to the at least one fuel device configured to control the at least one fuel device. The characterization device can be in wired or wireless communication with the electronic engine controller. The at least one fuel device can be a fuel pump or, a fuel metering unit, densimeter, or a flow divider valve.

A method of metering fuel by a fuel system can include calculating mass fuel flow—based on an equation mass fuel flow=K*CdA*√(dP*S) where K is a constant, CdA is a metering area (orifice area), dP is a pressure drop across the orifice, and S is a specific gravity of the fuel, storing a plurality of mass fuel flow conditions for the fuel device at plurality of metering areas, fuel temperatures, and fuel densities on a memory device of the characterization device, installing the fuel device within a fuel system, identifying the fuel device to an electronic engine controller, transferring fuel device performance data to the electronic engine controller and metering flow through the fuel device by the electronic engine controller based on the stored mass fuel flow data. The electronic engine controller can also aggregate characterization data from multiple fuel devices. The method allows for replacing at least one fuel device with a second fuel device, identifying the second fuel device to an electronic engine controller, transferring fuel device mass fuel flow data of the second fuel device to the electronic engine controller, metering flow through the second fuel device by the electronic engine controller based on the stored mass fuel flow data.

These and other features of the systems and methods of the subject disclosure will become more readily apparent to those skilled in the art from the following detailed description of the preferred embodiments taken in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

So that those skilled in the art to which the subject invention appertains will readily understand how to make and use the devices and methods of the subject invention without undue experimentation, preferred embodiments thereof will be described in detail herein below with reference to certain figures, wherein:

FIG. 1 is a schematic view of a fuel system according to an embodiment of the disclosure; and

FIG. 2 is a schematic view of a second embodiment of the fuel system according to an embodiment of the disclosure.

DETAILED DESCRIPTION

Reference will now be made to the drawings wherein like reference numerals identify similar structural features or aspects of the subject invention. For purposes of explanation and illustration, and not limitation, a partial view of an exemplary embodiment of a fuel system in accordance with the invention are shown in FIGS. 1 and 2, and are designated generally by reference character 100. The methods and systems of the invention can be used to improve fuel metering accuracy, by adding characterization devices to various fuel system components that contribute to an EEC's calculation of mass flow.

A fuel system's calculated flow is dependent on the data an Electronic Engine Controller (EEC) receives regarding the expectant conditions of the fuel and ambient conditions. The calculation of flow is a function of the pressure drop across an orifice of a device and the effective orifice area and density of the fuel flowing within or through that device. Specifically the expectant flow is calculated based on an orifice equation which is expressed as Wf (pph)=K*CdA*Sqrt (dP*S) where Wf is weight flow, where K is a constant, CdA is the effective orifice area, which consists of the geometric area (A) times the discharge coefficient (Cd), dP is the pressure drop across the orifice and S is the specific gravity of the fluid being metered.

FIG. 1 shows a schematic of fuel system 100. The fuel system 100 includes at least one fuel device 101, such as a fuel pump (101a), a fuel metering unit (101), a densimeter (101b), or a divider valve (101c). The fuel device 101 includes a housing 102 having at least one fuel channel therein 104. Each fuel device 101 within fuel system 100 includes a characterization device 103 having a memory device 109 therein for storing performance characteristics of the given fuel device 101 and passing them to the EEC 114. The characterization device 103 is used to improve the accuracy of the inputs (dP, CdA, density) into the calculation of fuel flow so that the difference between calculated and actual mass flow is reduced. The memory device 109 contains a variety of data depending on what the fuel device 101 is. For example if the fuel device 101 is an metering unit the memory device 109 will at least contain the relationship of metered flow to some output such as measured valve position

By using a characterization device 103, the actual performance characteristics of each specific fuel device 101 are mapped and stored the memory device 109 during production and passed on the EEC 114 during installation of the fuel device 101 into the fuel system 100, instead of the EEC 114 using expected or nominal performance characteristics of a default device.

The performance characteristics of each fuel device 101 are measured on a test rig and stored on the memory device 109 prior to the installation of the fuel device 101 within fuel system 100. The characteristics that are measured can include performance maps at various fuel temperatures, fuel densities, and fuel pressures. Further, if for instance, the fuel device is a fuel metering unit (FMU), which includes typically various valves, the valves can be run through various positions so that the performance of each particular configuration associated with varying flight conditions can be mapped and recorded on the memory device 109. Also internal leakage and the effects of internal leakage at various pressures and configurations can be recorded and mapped during testing. Previously, systems depended on a mechanical calibration of each individual fuel device such as a pump, fuel metering device, flow divider valve, densimeter or flow divider valve. Calculated metered flow was based on the nominal characteristics of these devices, as opposed their actual performance, and thus introduced errors in the calculation of fuel flow.

A data connection 110 allows characterization data to be read by EEC 114 from each characterization device 103 at installation. The data connection 110 to the EEC 114 can include multiple methods such as a serial link, such as an SPI bus, Quick Response code (QR) that get scanned and downloaded to the EEC 114 at installation, or other wireless communication. It is also considered that a physical cable with a DSU (data storage unit) plug that contains the memory device and gets inserted into the EEC 114 when the characterization device 103 is installed (as shown in FIG. 2). In this configuration the characterization device 103 plugs into the EEC so that it can be installed in the more friendly (i.e. less vibration, cooler) environment of the EEC 114. The characterization device is then connected by a lanyard 111 to the fuel device 101. Further if a fuel device 101 has to be replaced, the EEC 114 would read the particular characteristics of the new fuel device being installed and quickly be able to recalibrate the required performance.

The EEC 114 reads various performance characteristics of each fuel device at startup of an engine and stores said performance characteristics for use in the calculation of fuel flow. For instance, with a characterization device 103 on the FMU, the actual characteristic for each FMU or its components can be mapped. This greatly reduces sources of variation that are specific to the each fuel device 101 such as feedback device inaccuracy, metering window tolerances, and other characteristics. Further considering FMUs, regulation pressure (dP) of a pressure regulating valve (PRV) can be a function of the pressures that interface with it, the flow that the pressure regulating valve is bypassing (in the case of a positive displacement pump), the flow that it is throttling (in the case of a centrifugal pump), and fuel temperature. When a characterization device 103 is added to an FMU, and the characteristics are mapped at installation, the EEC 114 will know the specific characterization of the specific FMU in the fuel system (rather than assuming a nominal characteristic) and will therefore more accurately control the FMU. In the FMU the characterization device 103 will store the relationship between CdA and an output to the EEC (typically a sensor that is measuring metering valve position). This relationship can be mapped at a plurality of conditions of temperature, pressures, etc. Since dP is typically regulated by a regulator in the fuel metering unit, the regulator performance can also be mapped. The regulator performance (dP) depends on its input conditions, for example it may be a function of pump flow and pressures that it interfaces with and leakage flows. If these are known more accurately, then dP can be more accurately determined in the calculation of mass flow. Furthermore the parameters that interface with the pressure regulating valve such as flows, pressures and temperature may be received from other fuel devices such as pumps, flow divider valve and densimeter and these will be more accurately known due to their individual characterization devices.

The methods and systems of the present disclosure, as described above and shown in the drawings, provide for a fuel metering with increased accuracy. While the apparatus and methods of the subject disclosure have been showing and described with reference to embodiments, those skilled in the art will readily appreciate that changes and/or modifications may be made thereto without departing from the spirit and score of the subject disclosure.

Claims

1. A fuel device comprising:

a housing including at least one fuel channel configured to direct, meter, sense or pump fuel there through; and

a characterization device coupled to the housing including a memory chip, wherein the memory chip includes measured performance data of the at least one fuel channel.

2. The fuel device of claim 1, wherein the at least one fuel channel includes a metering valve.

3. The fuel device of claim 1, wherein the at least one fuel channel includes a pressure regulating valve.

4. The fuel device of claim 1, wherein the fuel device is a fuel metering unit, a fuel pump a flow divider valve, or a densimeter.

5. The fuel device of 1, wherein the characterization device includes a communication device configured to pass measured performance data to an electronic engine controller.

6. The fuel device of claim 1, wherein the measured performance data includes a plurality of fuel pressure, fuel density, fuel temperature conditions.

7. The fuel device of claim 1, wherein the measured performance data includes fuel leakage rates from the fuel device housing.

8. A fuel system comprising:

at least one fuel device configured to direct, meter, or pump fuel including a fuel characterization device configured to store measured performance data of the fuel device and communicate the measured performance data to an electronic engine controller; and

an electronic engine controller coupled to the at least one fuel device configured to control the at least one fuel device.

9. The fuel system of claim 8, wherein in the characterization device is in wireless communication with the electronic engine controller.

10. The fuel system of claim 9, wherein the wireless communication includes a quick response code.

11. The fuel system of claim 8, wherein the characterization device is physically coupled to the electronic engine controller.

12. The fuel system of claim 8, wherein the at least one fuel device includes a fuel pump, a fuel metering unit, a flow divider valve, or a densimeter.

13. The fuel system of claim 8, wherein the at least one device includes at least one of a fuel pump, a fuel metering unit, a flow divider valve, and a densimeter wherein each one includes a fuel characterization device.

14. The fuel system of claim 8, wherein the electronic engine controller is part of a gas turbine engine control.

15. A method of metering fuel by a fuel system comprising the steps of:

measuring mass fuel flow data through at least a first fuel device based a metering area or orifice area, a pressure drop across the orifice or metering area, and a specific gravity of fuel;

storing the mass fuel flow data of the fuel device on a memory device within a characterization device corresponding to the fuel device;

installing the fuel device and characterization device within a fuel system;

identifying the fuel device to an electronic engine controller;

transferring fuel device performance data to the electronic engine controller; and

metering flow through the fuel device by the electronic engine controller based on the stored mass fuel flow data.

16. The method of claim 15, wherein measuring mass fuel flow data includes a plurality of metering areas, fuel temperatures, and fuel densities.

17. The method of claim 15, further aggregating characterization data from multiple fuel devices.

18. The method of claim 15, further comprising replacing at least one fuel device with a second fuel device;

identifying the second fuel device to an electronic engine controller;

transferring fuel device performance data of the second fuel device to the electronic engine controller; and

metering flow through the second fuel device by the electronic engine controller based on the stored mass fuel flow data.