RU62086U1 - FUEL MEASURING SYSTEM OF THE AIRPLANE WITH COMPENSATION ON DIELECTRIC FUEL PERMEABILITY - Google Patents

Abstract

The utility model relates to aircraft instrumentation and can be used to measure stock and fuel consumption on board an aircraft. The proposed system contains a fuel mass flow meter installed in the line, fuel consumption sensors installed in the fuel and supply lines of the fuel tanks, as well as balancing and return lines, fuel level sensors and fuel level sensors installed in the fuel tanks, and dielectric permittivity sensors fuels installed in the lines and tanks of the aircraft power plant. The system also includes an on-board computer, a comparison device, an indicator, and electronic components: a bypass unit, a return unit, a refueling unit, a refueling unit, and a balancing unit. Based on information about the fuel coming from the sensors, alarms and system counter, as well as in accordance with the commands received from the external systems of the aircraft and information about the options for refueling, refueling and returning the aircraft, stored in the memory of the on-board computer, comparison device and refueling units , refueling and return, the system determines the amount of fuel refueling in the aircraft fuel tanks on the ground, the current fuel supply in flight, the amount of fuel dispensed from the aircraft, and the aerodynamic remainder approx fuel needed to return the plane. In addition, the system manages the process of refueling, refueling and dispensing fuel, and also ensures the timely adoption by the crew of a decision on the return of the aircraft for fuel. Based on the information generated by the fuel flow sensors installed in the return lines, and the mass fuel flow meter installed in the fuel delivery line, in the on-board computer of the system, as well as in the bypass unit and the refueling unit, the quantities of bypassed and issued fuel are taken into account, which can significantly reduce methodological measurement errors arising from the bypass and delivery of fuel.

If the transverse alignment of the aircraft is violated, the system balancing unit, based on the information received from the fuel consumption sensors installed in the balancing lines, using the data received from the on-board computer and the comparison device, generates control commands for balancing pumping of fuel, which allows to restore the required alignment of the aircraft.

Description

The proposed utility model relates to aircraft instrumentation and can be used to measure the supply and fuel consumption on board the aircraft.

Known on-board fuel measuring system designed to measure the fuel supply on board the aircraft [Patent for the invention of the Russian Federation No. 2156444, IPC G 01 F 23/26, publ. 2000]. It contains fuel level sensors installed in the tanks of the aircraft power plant, an on-board calculator of the volumetric fuel supply, a sensor of one of the characteristic parameters of the fuel - its temperature, installed in one of the tanks, a comparison device and an indicator. The mass fuel supply in this system is determined by correcting the calculated volumetric fuel supply value from the measured fuel temperature value.

The disadvantages of this system are the presence of a methodological error in calculating the fuel supply in mass units arising due to the dispersion of fuel temperatures between different tanks of the aircraft power plant and the inability to sufficiently accurately correct the entire volume of fuel on board the aircraft according to the fuel temperature measured in only one of the tanks, as well as the presence of an evolving error in measuring the volumetric fuel supply that occurs during the evolution of an aircraft in flight.

The evolutionary error that occurs during an airplane’s flight arises from the fact that an accurate determination of the volumetric fuel supply based on information about the fuel levels in fairly flat tanks, the vertical dimensions of which are much smaller than the horizontal dimensions, is possible only under conditions of horizontal flight without significant acceleration or with slight deviations from these conditions, when the interface between fuel and gas is in a relatively stationary state. Since a significant part of the fuel on the aircraft is contained in its flat wing tanks, and the flight of the aircraft is accompanied by significant overloads and spatial evolutions, the fuel interface and

The gas in the wing tanks fluctuates randomly during the flight, which makes it impossible to reliably determine the interface between the liquid and gas, accurately measure the level value and calculate the fuel supply.

These disadvantages are partially eliminated in the fuel and flow meter system of the aircraft [Patent for the invention of the Russian Federation No. 2182698, IPC 7 G 01 F 17/00, G 01 F 23/26, publ. 2002].

In this system, the fuel supply on board the aircraft is calculated not only on the basis of information from fuel level sensors installed in the fuselage tanks, but also on information from instant fuel consumption sensors installed in the main lines of the aircraft power plant, for which the fuel supply on the on-board computer is calculated the aircraft’s board as the difference between the amount of fuel loaded into the tanks of the power plant on the ground and the amount of fuel spent from these tanks in flight, the amount of fuel consumed VA is calculated by integrating in the on-board computer signals received from fuel consumption sensors during real-time consumption.

In this case, the fuel supply value calculated from the information on its consumption is displayed to the aircraft crew, and the fuel supply value determined from the fuel level information is used, firstly, to clarify the indicated supply and, secondly, to indicate in case of uncertainty fuel stock information caused, for example, by a failure of the flow meter channel. Since the spatial evolution of the aircraft does not affect the measurement error of instantaneous fuel consumption, this system allows with sufficient accuracy to control the fuel supply during spatial evolution of the aircraft in the initial stage of flight.

The disadvantage of this system is the presence of an ever-increasing error in the measurement of the fuel supply, calculated on the basis of information on fuel consumption. The indicated error continuously increases with the flight and by the end of it becomes significant due to the accumulation in real time of the integration error of the instantaneous flow rate.

To reduce this time-increasing error in a given

The system continuously compares with each other two values of the fuel supply: a value calculated on the basis of information about the instantaneous fuel consumption, and a value obtained on the basis of measuring fuel levels in the tanks, and if these values are not equal to each other, the measured fuel consumption values are adjusted accordingly.

In addition, in this system, in horizontal flight conditions, the current fuel supply value calculated from the fuel consumption information is periodically compared with one of the fixed fuel supply values obtained when the fuel level in the tank reaches a predetermined value, and if these values corresponding correction is formed.

The disadvantages of this system are absent in the closest to the proposed utility model and adopted as a prototype known on-board fuel metering system with compensation for static dielectric constant of the fuel [Patent for the invention of the Russian Federation No. 2186345 IPC 7 V 64 D 37/14, 37/4, G 01 F 23/26, publ. 2002].

The composition of the known system for measuring the amount of fuel in units of mass and mass fuel consumption on board an aircraft includes an on-board computer containing the first, second and third fuel quantity calculators, a comparison device containing the first and second comparison units, an indicator, fuel level sensors installed in the fuselage tanks, fuel consumption sensors installed in the refueling and supply lines of the wing tanks, fuel quantity indicators installed in the hanging tanks, as well as fuel static dielectric constant sensors installed in the fuselage tanks and refueling and supplies highways wing tanks (herein under static permittivity fuel understood dielectric fuel permeability measured at constant current or low frequency alternating current). Each of the outputs of each of the above fuel level sensors, fuel consumption sensors, and dielectric permittivity sensors of the fuel is connected to the corresponding input of the on-board computer, the output of each of the above fuel level sensors is connected to

the corresponding input of the comparison device, and the comparison device is connected to the on-board computer and to the indicator.

In the known system, the error in measuring the mass fuel supply on board the aircraft is substantially reduced, mainly due to the use at each stage of the flight of the aircraft: the initial, intermediate and final stages of various sources of information about the amount of fuel.

In this system, the fuel supply on board the aircraft is calculated at each stage of the flight using the following information sources:

а) at the initial stage of flight - according to the signals received from the fuel level signaling devices about the complete development of fuel from the fuel tanks of the first generation stage - suspension tanks;

b) in the intermediate stage of flight - according to the information received from the fuel consumption sensors and the dielectric permittivity sensors of the fuel mass consumption from the fuel tanks of the second generation stage - wing tanks;

c) in the final stage of the flight - according to information received from fuel level sensors and fuel permittivity sensors about the remaining fuel in the fuel tanks of the third generation stage - the fuselage tanks.

However, the following system has the following three drawbacks related to measuring the fuel supply, to the distribution of fuel in the tanks of the aircraft power plant, and to controlling the aircraft based on fuel information:

1) the presence of additional methodological errors in measuring the fuel supply;

2) the possibility of transverse imbalance of fuel in wing tanks;

3) the complexity and lack of effectiveness in managing the fueling of the aircraft, the delivery of fuel from the aircraft and the return of the aircraft for fuel.

The first drawback is that the presence of additional methodological errors in measuring the fuel supply on board an aircraft is manifested in the known system, firstly, due to the neglect of the amount of fuel that is pumped inside the aircraft through bypass lines, and, secondly, due to insufficiently accurate accounting

the amount of fuel delivered from the aircraft in flying tanker mode.

On the plane, in addition to the main lines intended for receiving fuel when refueling the aircraft with fuel on the ground and for refueling in flight, as well as for delivering fuel to the supply tanks of the aircraft’s power plant, additional — return — lines intended for transferring fuel inside the aircraft are also used between the various tanks of his power plant. Return lines are used, for example, when one of the tanks is overfilled with fuel in the case of transition of aircraft engines to an economical mode of operation, etc.

Since the transfer of fuel from one tank to another does not change the total fuel supply on board the aircraft, but only changes the distribution of fuel between the individual tanks of the aircraft power plant, the known system does not take into account the fuel consumption that is pumped along the return lines.

Return lines are designed to automatically return excess fuel from the supply tanks to the fuselage in order to avoid overfilling of the supply tanks in the event that the fuel does not have time to be produced from the supply tanks in a timely manner, for example, when fuel consumption is reduced by aircraft engines due to a change in their operation mode.

Failure to take into account in a known system the fuel consumption pumped along return lines leads to the appearance of additional methodological errors in measuring the fuel supply in flight.

So, for example, after pumping a certain amount of fuel from an outboard tank containing a quantity of fuel m _o into a consumable tank, the amount of fuel m ₁ excessively supplied to the consumable tank from the outboard is automatically pumped from it through the return line to the fuselage tank in order to avoid overflow tank.

However, after emptying and dumping the outboard tank, the fuel supply on board the aircraft, previously determined in the comparison device of the known system and recorded in the on-board computer, automatically decreases by m _o equal to the capacity of the dropped outboard tank, although the actual fuel supply on board the aircraft did not decrease by the value of m _o , and by the value of m _o -m ₁ ,

since the amount of fuel m _{1 was} not issued from the supply tank to the aircraft power plant, but returned to the fuselage tank.

Because the value of m _o always exceeds the value of m _o -m ₁ :

m _o > m _o -m ₁ ,

then the neglect of the amount of fuel pumped along the return line from the supply tank to the fuselage leads to an underestimation of the actual fuel supply by m ₁ , which causes a measurement error

δ ₁ = m ₁ , where

δ ₁ - additional methodological error in measuring the fuel supply caused by the neglect of the amount of fuel pumped along the return line;

m ₁ - unaccounted for the amount of fuel pumped along the return line.

The same drawback of the known system includes the presence of an additional methodological error in measuring the fuel supply on board an aircraft that occurs when fuel is delivered from an aircraft.

The indicated additional error is manifested when using the aircraft in the flying tanker mode. In this case, the fuel is dispensed from the aircraft with the maximum possible flow rate Q _m , which ensures the fastest refueling of the receiving aircraft in the air.

The flow rate Q _m of fuel emitted from the aircraft significantly exceeds the upper measurement limit q _{m of} fuel consumption sensors used in the known system and designed to operate only at nominal fuel transfer modes, when the fuel consumption does not exceed the upper measurement limit q _{m of} these sensors.

Since the measurement of the flow rate Q _m using the fuel flow sensors used in the system is impossible, the amount of fuel delivered from the aircraft is determined in the known system not by its actual consumption through the fuel delivery line, but by the difference between the fuel supply on the plane at the time of start of fuel delivery and fuel supply at the time of issue completion:

ΔM = - ,Where

ΔM is the difference between the fuel reserves on the plane at moments t ₁ and t ₂ ;

- fuel supply at time t ₁ ;

- fuel supply at time t ₂ ;

t ₁ - the moment of the beginning of fuel delivery;

t ₂ - the moment of the end of fuel delivery.

However, a similar method for determining the amount of fuel delivered from an aircraft is accompanied by an additional methodological measurement error, which arises mainly as a result of an erroneous accounting of the amount of fuel m ₂ that is not issued from the tanker aircraft to the receiver aircraft, but is used by the propulsion system of the tanker aircraft during the time of fuel delivery, which leads to the appearance of an additional methodological error in measuring the fuel supply on board a tanker plane, equal to the erroneously taken into account amount of fuel m ₂ :

δ ₂ = m ₂ , where

δ ₂ - additional methodological error in measuring the fuel supply arising from the release of fuel from an airplane;

m ₂ - the amount of erroneously recorded fuel.

The second disadvantage of the known system is the ability to distribute fuel unbalanced on the sides of the aircraft. An unbalanced distribution of fuel leads to a violation of the lateral alignment of the aircraft, since the masses of fuel in the right and left wing tanks of the aircraft are different.

In the known system, the current values of the masses of fuel in each of the wing tanks of a flying aircraft are determined by subtracting the mass of fuel continuously consumed from the wing tank from the mass of fuel poured into this tank when refueling the aircraft with fuel.

However, both of these values: the mass of fuel consumed from the tank and the mass of fuel poured into this tank are calculated in the known system with an error in measuring and integrating the instantaneous fuel consumption, as well as with an error in measuring the dielectric constant of the fuel in this tank.

In this regard, in the known system, an error in determining the actual mass arises and increases as fuel is consumed from the wing tanks

fuel located in each of the wing tanks, which leads to lateral imbalance of the aircraft in fuel, worsening its aerodynamic quality and maneuverability.

The lateral alignment of the aircraft may also be violated as a result of asymmetric dropping of cargo from one of the sides of the aircraft.

Such a misalignment is not counteracted by the known system and, like the imbalance in fuel, affects the aerodynamic quality and maneuverability of the aircraft.

The third disadvantage of the known system is the complexity and lack of effectiveness in managing the fueling of the aircraft, the distribution of fuel among the tanks of the power plant, the delivery of fuel from the aircraft during refueling in the air of the receiving aircraft, and the return of the aircraft in case of dangerous fuel production.

The objective of the proposed utility model is to increase the accuracy and efficiency of measuring the fuel supply and control the distribution of fuel by reducing additional methodological errors in measuring the amount of fuel on the plane, by improving the accuracy of controlling the fuel balance of the aircraft, and by increasing the efficiency of controlling the fueling and refueling of aircraft return of the aircraft for fuel.

To solve the problem, the aircraft’s fuel measuring system with compensation for the dielectric constant of the fuel, which includes an on-board computer, a comparison device, an indicator, fuel level sensors installed in the fuselage tanks, fuel consumption sensors installed in the fueling and supply lines of wing tanks, and dielectric sensors fuel permeability installed in the fuselage tanks and in the fuel and consumable lines of the wing tanks, as well as fuel level indicators, mounted in hanging tanks, the output of each of the aforementioned fuel level sensors, fuel consumption sensors and sensors of the dielectric constant of the fuel is connected to one of the corresponding inputs of the on-board computer, and the output of each of the said fuel level sensors is connected to one of the corresponding inputs of the comparison device connected to on-board calculator and with indicator, supplemented by new elements and links.

The proposed system differs from the prototype in that it includes an overflow unit, a return unit, a refueling unit, a refueling unit, a balancing unit and a fuel mass flow meter installed in the fuel delivery line. In addition, the system uses additional fuel flow sensors installed in the balancing lines and return lines, additional fuel consumption sensors and additional fuel dielectric permeability sensors installed in the filling lines of the fuselage tanks, as well as additional fuel level sensors installed in the fuselage tanks.

Moreover, each of the above additionally introduced blocks of the proposed system is connected to the on-board computer by corresponding two-way information communication, the output of each of the above additional fuel consumption sensors and the above additional fuel dielectric permittivity sensors installed in the fueling lines of the fuselage tanks is connected to one of the corresponding inputs of the refueling unit , the output of each of the above additional fuel consumption sensors installed in the ball alignment lines, connected to one of the inputs of the balancing unit, equipped with outputs, each of which is designed to connect to the control input of the actuator of the power plant located in one of the balancing lines, and the comparison device is connected to the on-board computer via two-way information communication.

The output of each of the above additional fuel flow sensors installed in the return lines is connected to one of the corresponding inputs of the bypass unit, the output of each of the above additional fuel level sensors installed in the fuselage tanks is connected to one of the corresponding inputs of the return unit, and the output of the above the entered fuel mass flow meter is connected to the input of the refueling unit, equipped with an output for connecting to the control input th power plant mechanism located in the fuel delivery line.

The on-board computer of the proposed system is equipped with two-way information communication for connecting to external systems of the aircraft, and the refueling unit, refueling unit and balancing unit of the proposed system are equipped with each input for connecting to one of the corresponding outputs of external systems.

The operation of the proposed system is illustrated by the Figure.

The figure shows a functional diagram of the proposed system and the following notation is introduced: 1 - fuel level sensor, 2 - fuel dielectric constant sensor, 3 - fuselage tank, 4 - fuel consumption sensor, 5 - fuselage tank supply line, 6 - return line, 7 - fuselage tank filling line, 8 - supply tank, 9 - supply tank filling line, 10 - supply tank supply line, 11 - fuel mass flow meter, 12 - wing tank, 13 - fuel delivery line, 14 - cr flow line of the left tank, 15 - the fuel line of the wing tank, 16 - the balancing line, 17 - the actuator of the power plant, 18 - the fuel level switch, 19 - the suspension tank, 20 - the flow line of the hanging tank, 21 - the on-board computer, 22 - the bypass unit, 23 - refueling unit, 24 - refueling unit, 25 - refund unit, 26 - balancing unit, 27 - comparison device, 28 - indicator, 29 - external systems.

The double arrows in the Figure show the directions of fuel movement in each of the lines 5, 6, 7, 9, 10, 13, 14, 15, 16 and 20.

The output of each fuel level sensor 1 installed in each fuselage tank 3 is connected to one of the corresponding inputs of the on-board computer 21. The output of each of the dielectric permittivity sensors of fuel 2 installed in the fuselage tanks 3, as well as the output of each fuel consumption sensor 4 and the output of each the dielectric constant of the fuel 2 installed in the supply lines 14 and in the fuel line 15 of the wing tanks 12, is connected to the corresponding input of the on-board computer 21.

The output of the mass flow meter 11 installed in the fuel delivery line 13 is connected to one of the inputs of the refueling unit 24, the other input of which is connected to the corresponding output of the external systems 29, and the output is connected to the control input of the actuator of the power plant 17,

installed in the fuel delivery line 13.

The output of each of the fuel consumption sensors 4 installed in the balancing lines 16 is connected to one of the inputs of the balancing unit 26, each of the outputs of which is connected to the control input of one of the actuators of the power plant 17, each installed in one of the balancing lines 16.

The output of each of the fuel level sensors 18 installed in the overhead tanks 19 is connected to the corresponding input of the comparison device 27, the output of which is connected to the indicator 28, and the output of each of the fuel level sensors 18 installed in the fuselage tanks 3 is connected to the corresponding input of the return unit 25.

The output of each of the fuel consumption sensors 4 installed in the return lines 6 is connected to the corresponding input of the bypass unit 22.

The output of each of the fuel consumption sensors 4 and the output of each of the dielectric permittivity sensors of the fuel 2 installed in the fueling lines 7 of the fuselage tanks 3 is connected to one of the corresponding inputs of the fueling unit 23.

Each of the blocks of the proposed system: the bypass block 22, the refueling block 23, the refueling block 24, the return block 25 and the balancing block 26 is connected to the on-board computer 21 by a corresponding two-way information communication.

Two-way information communication also connects to the on-board computer 21 a comparison device 27. Each of the outputs of the external systems 29 is connected to the corresponding input of one of the following blocks: refueling unit 23, refueling unit 24 and balancing unit 26; external systems 29 are connected to the on-board computer 21 two-way information communication.

The proposed system is designed to measure the stock and fuel consumption and control the distribution of fuel in the aircraft power plant when refueling and refueling the aircraft with fuel, with the fuel balancing of the aircraft, as well as when returning the aircraft for fuel. The power plant of the aircraft contains tanks, actuators and highways, including suspension 19, wing 12, fuselage 3 and consumable 8 tanks, actuators of the power plant 17,

refueling 7, 9 and 15, consumables 5, 10, 14 and 20, return 6 and balancing 16 lines, as well as the fuel delivery line 13; as an actuator of a power plant, for example, a fuel transfer unit can be used.

Suspended 19, wing 12 and fuselage 3 tanks of the power plant are designed for storage and delivery of fuel to consumable tanks 8, and consumable tanks 8 are used for uninterrupted supply of fuel to aircraft engines.

Filling lines 7, 9 and 15 are used for refueling in tanks, fuel lines 5, 10, 14 and 20 are used for fueling from tanks, fuel delivery line 13 provides for the delivery of fuel from a tanker aircraft to a receiving aircraft, and power actuators Installations 17 are intended for pumping fuel from tanks or into tanks along the corresponding highways. In addition to interacting with the executive mechanisms of the aircraft power plant, the proposed system can also exchange information with external aircraft systems: gyroscopes, navigation systems, etc.

Refueling an aircraft using the proposed system is as follows.

In the process of designing an aircraft, its tanks, depending on the order in which fuel is generated from them, are divided into the following four groups: a group of tanks that are not fully developed (consumable tanks 8), a group of tanks of the first production stage (hanging tanks 19), and a group of tanks of the second production stage ( wing tanks 12) and a group of tanks of the third generation stage (fuselage tanks 3).

When refueling an airplane with fuel on the ground during preflight preparation, refueling of each tank is carried out in accordance with one of the refueling options, which is included in the following list of options: option 1 (Full + PB), option 2 (Full), option 3 (Basic) and option 4 (Partial); here PB - hanging tanks 19.

In option 1, designed for the long haul of the aircraft or for its use in the flying tanker mode, all suspension tanks 19 and all wing tanks 12 are completely filled with fuel. All fuselage tanks 3 are filled with fuel to the level of entry into each fuselage tank 3 of the return line 6.

In option 2, intended for standard fueling of an airplane based on several aerodromes remote from one another, the suspension tanks 19 are not refueling and are not suspended from the airplane.

In option 3, designed for standard fueling of an aircraft based on one aerodrome, hanging tanks 19 and wing tanks 12 are not refueled; the fuselage tanks 3 are completely filled with fuels (up to the input level into each fuselage tank 3 of the return line 6).

In option 4, intended mainly for training flights of the aircraft, only the fuselage tanks 3 are refueled, and the fuselage tanks 3 are not completely filled (below the entry level into the fuselage tank 3 of the return line 7).

When refueling an aircraft with fuel according to option 1, the proposed system uses code data on the capacity of each of the suspension tanks 19, entered into the memory of the comparison device 27 when installing the proposed system on the aircraft, and the specific number of the fueled suspension tank 19 is determined in the comparison device 27 by the signal generated by the fuel level switch 18 installed in this tank.

When refueling an aircraft with fuel according to one of the options 2, 3 or 4, the amount of fuel required to refuel the wing tanks 12 and fuselage tanks 3 on the ground is determined by the selected refueling option, which is entered by the crew from external systems 29 into the refueling unit 23 in the form of a code for this option . The amount of fuel actually refueled on the ground in the wing tanks 12 is taken into account in the on-board computer 21 based on the integration over the time of fueling of the signals generated by the fuel consumption sensors 4 installed in the fueling lines 15 of the wing tanks 12, taking into account the information generated by the sensors of the dielectric constant of the fuel 2 installed in these highways.

Accounting for the amount of fuel actually refueled on the ground in the fuselage tanks 3, and the correspondence of this quantity to the selected refueling option, is performed in the refueling block 23 based on the signals received in this block from the fuel level sensors 1 installed in the fuselage tanks 3, taking into account the received block

refueling 23 information from the dielectric permittivity sensors of the fuel 2 installed in these tanks.

In flight, the generation of fuel from tanks using the proposed system is as follows.

The fuel consumed during the flight enters the consumable tanks 8 from the outboard 19, wing 12, and fuselage 3 tanks through the consumable lines 20, 14, and 5, respectively, of the indicated tanks and the fuel lines 9 of the consumable tanks 8. From the consumable tanks 8, the fuel is supplied to the aircraft engine power supply lines through the supply lines 10 of the supply tanks 8.

The sequence of fuel generation from the tanks of a flying airplane corresponds to the refueling option, the code of which is entered by the crew from external systems 29 into the on-board computer 21 through the corresponding input of the refueling unit 23 and the corresponding two-way information connection connecting the on-board computer 21 to the refueling unit 23.

If a refueling code according to option 1 is entered into the on-board computer, then at the initial stage of the flight fuel is generated from each outboard tank 19 through the supply line 20 of this tank until the fuel level switch 18 is set to zero at that outboard tank 19, after which the outboard tank 19 is automatically reset from the aircraft.

Accounting for a portion of fuel equal to the fuel capacity of the dumped hanging tank 19 is made in accordance with the code corresponding to the number of this tank in the comparison device 27, in the memory of which code data on the numbers and capacities of each of the hanging tanks 19 are entered.

In the intermediate stage of the flight, fuel is generated from the wing tanks 12 through the supply lines 14 of these tanks and the filling lines 9 of the supply tanks 8 until the emptying of each wing tank 12.

Accounting for the current amount of fuel continuously consumed from each wing tank 12 in the intermediate stage of flight is carried out in the on-board computer 21 by integrating over time the signals from the fuel consumption sensors 4 installed in the supply lines 14 of the wing tanks 12, with the correction of the integration results by information

generated by the sensors of the dielectric constant of the fuel 2 installed in these highways.

In the final stage of the flight, the fuel enters the consumables 8 from the fuselage tanks 3 through the consumables 5 of these tanks and the filling lines 9 of the consumables 8.

Fuel production from the fuselage tanks 3 is carried out unhindered only to the fuel level in each of these tanks, which corresponds to the aeronautical fuel balance determined in the return unit 25 according to the signals generated by the fuel level sensors 18 installed in each fuselage tank 3 at a predetermined height from its bottom.

If the aircraft is used in the flying tanker mode, the fuel delivered from it during the flight is pumped using the actuator of the power plant 17 located in the fuel delivery line 13 to the receiving line of the receiving aircraft.

A portion of fuel intended for dispensing from a tanker aircraft should correspond to the required refueling option. The refueling option is selected by the crew from the list of established refueling options in accordance with the requirements of the receiving aircraft.

Information on refueling options, containing data on the rate of fuel delivery, the amount of fuel dispensed and the code of each refueling option, is entered into the memory of the refueling unit 24 during its design.

The code signal corresponding to the refueling option selected by the crew is supplied from external systems 29 to the corresponding input of the refueling unit 24 and initiates the issuance of a control signal from the output of the refueling unit 24 to the control input of the actuator of the power plant 17 located in the fuel delivery line 13. Accounting for the amount of fuel dispensed along the aforementioned highway with a given rate of delivery is carried out in the refueling unit 24 based on the signals generated by the mass flow meter top Libya 11. At the same time, the data on the amount of fuel delivered is continuously transmitted via two-way information communication from the output of the refueling unit 24 to the input of the on-board computer 21. After issuing the quantity from the tanker aircraft

fuel corresponding to the refueling option selected by the crew, in the refueling block 24 a signal is issued for the end of fuel delivery coming from its output to the control input of the actuator of the power plant 17 located in the fuel delivery line 13, and fuel delivery to the receiving aircraft is stopped.

When flying an aircraft refueled according to one of the options 1 or 2, there may be a difference in fuel consumption from the wing tanks 12, in which the fuel consumption through each of the supply lines 14 of the wing tanks 12 is not equal to each other.

Because unequal consumption of fuel from the wing tanks 12 leads to a violation of the lateral alignment of the aircraft, the proposed system provides control of the balanced transfer of fuel from one wing tank 12 to another wing tank, the purpose of which is to restore the lateral alignment of the aircraft.

When refueling the wing tanks 12 in the on-board computer 21 based on the information received from the fuel consumption sensor 4 and the dielectric constant of the fuel 2 installed in the refueling line of the wing tanks 15, the amount of fuel charged to the above tanks and the calculated fuel supply in wing tanks 12 are transmitted via two-way information communication for storage in the memory of the comparison device 27.

When in-flight fuel is consumed from the wing tanks 12, the on-board computer 21, based on information received from the fuel consumption sensors 4 and the dielectric permittivity sensors 2 of the fuel installed in each of the supply lines 14 of these tanks, continuously calculates the amount of fuel consumed from each wing tank 12 , by integrating the signals of the fuel consumption sensors 4 according to the consumption time, taking into account the information received from the sensors of the dielectric constant of the fuel 2 installed in the consumables trawls 14. The calculated data is transmitted via two-way information communication from the on-board computer 21 to the comparison device 27.

In the comparison device 27 using obtained from the onboard

the calculator 21 data on the current amount of fuel consumed from the wing tanks 12, as well as data on the initial fuel supply in these tanks stored in the memory of the comparison device 27, determines the current values of the fuel residues in each of the wing tanks 13. In the case where the difference between the current values of the indicated fuel residues exceed the set limit, a signal is generated in the comparison device 27 to pump a given portion of fuel from the wing tank 12 with a large remaining fuel to the wing tank 12 with a smaller fuel tank tkom. The specified signal is received via the corresponding two-way information communication from the comparison device 27 to the on-board computer 21 and then, through the corresponding two-way information communication, it is transmitted to the balancing unit 26, which generates a control command for pumping a given portion of the fuel to the control input of the actuator of the power plant 17, located in one of the balancing lines 16, corresponding to the desired direction of pumping.

Monitoring the pumping of a given portion of the fuel along the aforementioned line is performed in the balancing unit 26 by continuously integrating over the pumping time a signal taken from the fuel consumption sensor 4 installed in this line. If the pumped-over amount of fuel is equal to each other and the given portion of fuel in the balancing unit 26, a pumping stop command is generated, which arrives at the control input of the corresponding actuator of the power plant 17, after which the pumping stops.

In the case when the violation of the lateral alignment is caused by an imbalance of cargoes arising, for example, when the load is unbalanced from one of the sides of the aircraft, the centering is restored by the signal received at the corresponding input of the balancing unit 26 from the onboard gyroscope that is part of external systems 29. In accordance with the received signal in the balancing unit 26, a pumping instruction is generated, which arrives at the control input of the actuator of the power plant 17 located in the balancers ary line 16 corresponding to the desired direction of transfer.

After eliminating the imbalance by pumping fuel from one of the wing

tanks 12 to the opposite wing tank from external systems 29 to the balancing unit 26 receives a signal to restore the lateral alignment of the aircraft, and the balancing unit 26 issues a command to stop pumping fuel to the corresponding actuator of the power plant 17.

If in flight the fuel is pumped to the return lines 6 from the supply tanks 8 to the fuselage tanks 3, then in these cases the amount of fuel pumped through the return lines 6 is calculated based on the information generated by the fuel consumption sensors 4 installed in the return lines 6.

In this case, the signal generated by each of the aforementioned fuel consumption sensors 4 is supplied to the corresponding input of the bypass unit 22, where the signal is integrated over the bypass time. Information on the amount of fuel pumped through each of the return lines 6 is transmitted via two-way information communication from the output of the bypass unit 22 to the input of the on-board computer 21, in which the data on the remaining fuel in each of the tanks 3 and 12 is adjusted in accordance with the data received from the unit bypass 22 information.

At the final stage of the flight of the aircraft, when the fuel is completely generated from the hanging 19 and wing 12 tanks, the fuel production from the fuselage tanks 3 is controlled in the on-board computer 21 by the signals taken from the fuel level sensors 1 and the dielectric permittivity of the fuel 2 installed in these tanks. Data on the current fuel balance in the fuselage tanks 3 is transmitted from the on-board computer 21 to the comparison device 27 via the corresponding two-way information communication.

At the same time, on-board computer 21 from external systems 29 continuously receives navigation information about the distance of the flying aircraft from the nearest airfield via the corresponding two-way information connection. This information is transmitted through the corresponding two-way information communication from the on-board computer 21 to the return unit 25, in which, taking into account the fuel consumption per kilometer of flight, the minimum amount of fuel needed to return the aircraft to the nearest airfield is determined. The received data on the minimum required amount of fuel is transmitted from the return unit 25 to

a comparison device 27 through the on-board computer 21 for the corresponding two-way information links.

In the comparison device 27, a continuous comparison is made of the current fuel balance in the fuselage tanks 3 with the amount of fuel minimally necessary for returning the aircraft, and when these values are equal, a “Return” signal is generated that alerts the crew from the output of the comparison device 27 to indicator 28.

With the further development of fuel from the fuselage tanks 3, in case the fuel level in any of these tanks reaches the installation point of the fuel level switch 18, this indicator generates and transmits to the return unit 25 a signal about the minimum fuel balance equal to the aerodynamic balance. The arrival of the specified signal in the return unit 25 leads to the formation in this unit of a command to achieve an aerodynamic balance, transmitted via the corresponding two-way information links from the return unit 25 through the on-board computer 21 to the comparison device 27 and, further, from the output of the latter to the indicator 28. B In this case, a dangerous signal “Fuel is low” is displayed on indicator 28, requiring a decision by the crew on an unconditional landing.

Thus, in the proposed fuel measuring system of the aircraft with compensation for the dielectric constant of the fuel, the problem is solved.

Firstly, in the proposed system, additional methodological errors in measuring the fuel supply on an airplane caused by the neglect of the amount of fuel pumped along return lines 6 have been reduced.

These errors were significantly reduced by measuring the amount of bypassed fuel in the bypass block 22 based on information received from the fuel flow sensors 4, each of which is installed in one of the return lines 6, and adjusting the values of the actual fuel supply in the on-board computer 21 each of the tanks 3, 12 according to information about the amount of bypassed fuel received in the on-board computer 21 from the bypass unit 22 via the corresponding two-way information communication.

An additional methodological error in measuring the fuel supply arising from the delivery of fuel from a tanker aircraft to a receiving aircraft is significantly reduced by taking into account the mass of fuel delivered to the on-board computer 21, which is determined in the refueling unit 24, which processes the information received from the mass flow meter 11 installed in the fuel delivery line 13; while the data on the mass of fuel delivered from the aircraft is transmitted to the on-board computer 21 from the refueling unit 24 via the corresponding two-way information communication.

Secondly, the proposed system provides restoration of the lateral alignment of the aircraft, violated either due to the imbalance of fuel in the opposite wing tanks 12 of the aircraft, or as a result of asymmetric dropping of cargo from one of the sides of the aircraft.

Violation of the lateral balancing of the aircraft for fuel is eliminated in the proposed system by controlling the fuel transfer through the balancing lines 16. The formation of the balancing fuel pumping control signals and the amount of fuel pumped are controlled in the balancing unit 26 based on the information received from this fuel flow sensor 4 installed in each from balancing lines 16, taking into account the data on the fuel supply in each of the wing tanks 12, received by the balancer block 26 Application of the onboard computer 21 to two-way data communication.

In case of violation of the transverse alignment of the aircraft as a result of asymmetric dropping of the load in the balancing unit 26, in addition to the above procedure for restoring the transverse alignment of the aircraft, the commands received at the corresponding input of this unit from external systems 29 are also taken into account.

Thirdly, the proposed system makes it possible to simplify and make more efficient the management of fueling an airplane on the ground, refueling an airplane with fuel in flight, and also returning an airplane for fuel.

The simplification and improvement of control efficiency using the proposed system is achieved through the use of refueling blocks 23, refueling 24 and return 25 in it, each of which contains data codes on the most

effective options, respectively, refueling, refueling and return. At the same time, fueling is controlled in the fueling unit 23 on the basis of information received from fuel consumption sensors 4 and dielectric permittivity sensors 2 installed in the fueling lines 7 of the fuselage tanks 3 using data exchange between the fueling unit 23 and the on-board computer 21 through appropriate two-way information communication and taking into account the commands received at the corresponding input of the refueling block 23 from external systems 29.

Refueling is controlled in the refueling block 24 based on the commands transmitted to this block by external systems 29 and the information received from the mass flow meter 11, taking into account the data exchange between the refueling block 24 and the on-board computer 21 via the corresponding two-way information communication.

The generation of information on the need for fuel return is generated in the return unit 25 based on the signals generated by the fuel level sensors 18 installed in the fuselage tanks 3, taking into account the data exchange between the return unit 25 and the on-board computer 21 via the corresponding two-way information communication; the generated information is transmitted through the comparison device 27 to the indicator 28 to alert the crew.

Claims (1)

Fuel measuring system of an aircraft with compensation for dielectric permittivity of a fuel, comprising an on-board calculator, a comparison device, an indicator, fuel level sensors installed in the fuselage tanks, fuel consumption sensors installed in the fueling and supply lines of the wing tanks, and dielectric permittivity sensors of the fuel installed in the fuselage tanks as well as in the refueling and consumable lines of the wing tanks, and fuel level indicators installed in the hanging tanks, with access to each of said fuel level sensors, each of said fuel consumption sensors, and each of said fuel permittivity sensors is connected to one of the corresponding inputs of the on-board computer, and the output of each of said fuel level sensors is connected to one of the corresponding inputs of the comparison device connected to the indicator and connected to the on-board computer, characterized in that it includes an additional bypass unit, a return unit, a refueling unit, a charge unit In addition, the balancing unit and the fuel mass flow meter installed in the fuel delivery line, fuel consumption sensors are additionally installed in the filling lines of the fuselage tanks, as well as in the balancing and return lines, the dielectric permittivity sensors are additionally installed in the filling lines of the fuselage tanks, level indicators fuels are additionally installed in the fuselage tanks, the comparison device is connected to the on-board computer via two-way information communication link, each of the mentioned additionally entered blocks: bypass block, return block, refueling block, refueling block and balancing block is connected to the on-board computer by corresponding two-way information communication, and the output of the mentioned additionally entered fuel mass flow meter is connected to the corresponding input of the refueling block, when this is the output of each of the fuel consumption sensors and the dielectric permittivity sensors additionally installed in the fueling lines of the fuselage tanks VA is connected to one of the corresponding inputs of the refueling unit, the output of each of the fuel flow sensors additionally installed in the balancing lines is connected to one of the corresponding inputs of the balancing unit, the output of each of the fuel flow sensors additionally installed in the return lines is connected to one of the corresponding inputs of the block the bypass, the output of each of the fuel level alarms additionally installed in the fuselage tanks is connected to one of the corresponding inputs of the return unit , the balancing unit is equipped with outputs, each of which is designed to connect to the control input of one of the actuators of the power plant located in one of the balancing lines, the refueling unit is equipped with an output designed to connect to the control input of the actuator of the power plant located in the fuel delivery line , the on-board computer is equipped with two-way information communication, designed to connect to external aircraft systems, and the refueling unit, b the refueling lock and the balancing unit are equipped with each input intended for connection to one of the corresponding outputs of the aircraft's external systems.