RU2679337C1 - Supersonic ramjet engine traction and economic characteristics increasing method (options) - Google Patents

Abstract

FIELD: engines and pumps.SUBSTANCE: supersonic ramjet engine traction and economic characteristics increasing method includes flowing into its flow path supersonic air stream compression with the air intake device multi-jerk braking surface, air flow into the combustion chamber supply through the flow path, the fuel into the combustion chamber supply and the fuel combustion products discharge through the jet nozzle. Also performing the air flow removal, and the air duct closing by the closing device. Removal is performed from the braking surface in front of the air intake device neck through the grid of holes and the air duct into the external air flow reduced pressure acting zone, after the static pressure increase in the air intake device neck. At that, the air flow part removal is carried out through the opening in the flow path wall at the combustion chamber input and the combustion chamber and the jet nozzle cavity. For the air duct closing device operation using the air flow increased static pressure at the combustion chamber input after the fuel ignition therein.EFFECT: invention is aimed at the air from the air intake device removal communication channel closing device design simplification and the aircraft side wall additional heating elimination.2 cl, 3 dwg

Description

The invention relates to ramjet engines in which the working fluid is used to create an air-jet jet, characterized by compression due to high-speed pressure, in particular, to supersonic (SPVRD).

A known method of starting a supersonic air intake device (VZU), JP patent No.200992823, comprising compressing a supersonic air flow by a multi-jump braking surface of the VZU, with the removal of part of the air flow from the braking surface in front of the throat of the VZU through the grill of holes and the communication channel into the low-pressure zone of the external air flow through the hole on the outside of the housing, measuring the static pressure in the throat of the VZU with a sensor and, after increasing the static pressure in the throat of the VZU, blocking the channel with generalization by the device overlap. The known method allows to increase the recovery coefficient of the total pressure at the corner point of the throttle characteristic of the VZU due to the additional reduction of the area of the passage section of its throat. When using the known method of starting a HVD as a part of an SPVRD flow path, the static pressure in the throat (minimum passage section) of the VZU increases, which makes it possible to proportionally increase the working pressure of the fuel combustion products in the combustion chamber of the SPVRD due to a decrease in the critical cross-sectional area of its jet nozzle, when This increases the degree of expansion of the combustion products of the fuel in the socket (expanding part) of the jet nozzle and their speed at the exit of the jet nozzle. This makes it possible, with the same dimensions of the engine and fuel consumption, to increase the thrust of the engine, or, to obtain the necessary thrust of the engine, to reduce its dimensions and fuel consumption in its combustion chamber, therefore, in both cases, to increase the traction and economic characteristics of the engine.

The essential features of the prototype, which coincide with the essential features of the first version of the proposed method for increasing the traction and economic characteristics of the airjet engine, are the following: a method of increasing the traction and economic characteristics of a supersonic ramjet engine, including compressing a supersonic air stream flowing into its flow path, a multi-jump braking surface air intake device, with the flow of air through the flow path into the combustion chamber, supply fuel into the combustion chamber and the discharge of fuel combustion products through the jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the air intake device through the grill of holes and the duct into the low pressure zone of the external air flow.

The essential features of the prototype, which coincide with the essential features of the second variant of the proposed method for increasing the traction and economic characteristics of the airjet engine, are the following: a method of increasing the traction and economic characteristics of a supersonic ramjet engine, including compressing a supersonic air stream flowing into its flow path, a multi-jump braking surface air intake device, with the flow of air through the flow path into the combustion chamber, supply fuel into the combustion chamber and the discharge of fuel combustion products through the jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the air intake device through the hole grill and the air duct to the low-pressure zone of the external air flow, and the duct is blocked by the shutoff device, after increasing the static pressure in throat of air intake device.

When implementing the well-known method of starting a VZU as part of an SPVRD, the use of static pressure in the throat of an air intake device to block the duct leads to the structural complexity of the overlap device: the presence of a static pressure sensor in the throat of the air intake device, a converter (pos. 19) of the static pressure sensor signal, a solenoidal magnet, the winding of which is communicated with the signal converter of the static pressure sensor, slide slide gate mounted on the rails and preloaded th compression spring, a gripper holding the slide slide in the open position, driven by a solenoidal magnet. In addition, the removal of a part of the air flow from the braking surface in front of the throat of the OVC to its outer wall leads to its additional heating, due to the fact that the air flow discharged after compression by the multi-jump braking surface has an increased temperature.

The technical problem, the solution of which is aimed at the proposed technical solution, is to simplify the design of the airjet and eliminate the additional heating of the outer wall of the VZU.

To achieve the named technical result in the first variant of the method of increasing the traction and economic characteristics of the airjet engine, which includes compressing a supersonic air flow flowing into its flow path, a multi-jump braking surface of the air intake device, supplying air flow through the flow path to the combustion chamber, supplying fuel to the combustion chamber and discharge of fuel combustion products through a jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the intake stroystva through the grate openings in the duct and a low pressure zone of action of the external air flow, removing a portion of the air flow is carried out through an opening in the wall of the flow path at the entry portion of the combustion chamber and the cavity combustion chamber and the nozzle.

To achieve the named technical result in the second variant of the method of increasing the traction and economic characteristics of the airjet engine, which includes compressing a supersonic air stream flowing into its flow path, a multi-jump braking surface of the air intake device, supplying air flow through the flow path to the combustion chamber, supplying fuel to the combustion chamber and discharge of fuel combustion products through a jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the intake devices through the grid of holes and the duct into the low pressure zone of the external air flow, and the duct is blocked by the shutoff device, after increasing the static pressure in the throat of the air intake device, part of the air flow is removed through the hole in the wall of the flow path at the entrance to the combustion chamber and the chamber cavity combustion and jet nozzle, and to operate the device blocking the duct use increased static pressure of the air flow at the inlet to Yeru combustion after ignition of fuel therein.

Distinctive features of the first version of the proposed SPVRD are the following: the part of the air flow is removed through an opening in the wall of the flow path at the entrance to the combustion chamber and the cavity of the combustion chamber and the jet nozzle.

Distinctive features of the second variant of the proposed SPJD are the following: the part of the air flow is discharged through an opening in the wall of the flow path in the area of the entrance to the combustion chamber and the cavity of the combustion chamber and the jet nozzle, and an increased static pressure of the air flow at the chamber inlet is used to trigger the airway shutoff device combustion after ignition of fuel in it.

Due to the presence of these distinctive features in conjunction with the well-known (indicated in the restrictive part of the formula) the following technical result is achieved - the design of the SPVRD is simplified, the additional heating of the upper wall of the VZU is excluded and the possibility of restarting the SPVRD is ensured.

The proposed technical solution can find application in the development of an aircraft with an airjet engine to simplify the design of an airjet engine that provides increased traction and economic characteristics.

The method is illustrated by the device shown in the drawings, FIG. 1-3.

In FIG. 1 is a cross-sectional view of an air intake manifold that illustrates a device for removing part of the air flow from the braking surface in front of the throat of a turbojet engine and a device for shutting off an air duct made in the form of a check valve.

In FIG. 2 is a section A-A of FIG. 1, further illustrating the design of the check valve in the duct.

In FIG. 3 is a front view of the SPVRD, explaining the design of the lattice of holes on the braking surface of the VZU in front of its throat and the holes in the wall of the flow path at the entrance to the combustion chamber (the place where the SPVRD body is torn out).

The SPVRD shown in the drawings is made in the form of a housing 1 equipped with a device 2 for attachment to an aircraft (not shown in the drawings), and containing a flow path including a VZU 3 with a multi-jump surface for braking the air flow formed by braking surfaces 4 and 5 located at different angles to the incident air flow (W _p ), throat 6 with the smallest bore and insulator 7 with a slightly expanding bore (by the amount of increase in the thickness of the boundary layer of the air flow), to accommodate oblique jumps s of pressure closing a direct jump in pressure of the air flow in the smallest orifice section of the throat 6, diffuser 8, combustion chamber 9, jet nozzle 10 with a critical section 11. A grid of 12 holes 13 is made in front of the throat 6 on the braking surface 5. In the wall 14 of the flow path section 15 of the entrance to the combustion chamber 9 is made a hole that can be made as a single continuous hole (not shown), and in the form of several holes 16 distributed over section 15. The housing 1 is equipped with an air duct 17 communicating from The hole 13 of the grill 12 with the holes 16 of the section 15. The duct 17 is equipped with a shut-off device made in the form of a check valve containing a shutter 18 located in the duct 17 on the axis of rotation 19, which is installed perpendicular to the direction of the exhaust air flow above the passage section of the duct 17 behind the shutter 18 in hinges 20 made in the wall 21 of the duct 17. Before the shutter 18 along the periphery of the perpendicular section of the duct 17, a seat 22 for the shutter 18 is made. On the axis 19 there is a spring 23 fixed one to the end to the wall 21, and the second end to the shutter 18, and the pressing shutter 18 to the seat 22. The housing 1 is equipped with an ignition device 24 in communication with the combustion chamber 9 and provided with its switching device 25, the fuel supply system 26 to the combustion chamber and system 27 control communicated by electric communication lines with the system 26 for supplying fuel to the combustion chamber and the device 25 for switching on the igniter device 24.

SPARD works as follows. When the aircraft is accelerated by a separate booster device (not shown in the drawings) to a supersonic flight speed, due to the braking of the air flow W _n (Fig. 1) in the wind turbine 3 with braking surfaces 4 and 5 located at different angles to the horizon, the air flow is abruptly braked in oblique pressure surges reflected from these surfaces, with a sequential stepwise increase in pressure after each shock, which provides the maximum static air pressure at the inlet to the throat 6. The maximum air flow through the throat is 6 is divided by the minimum area of its passage section and the speed of sound in this section, which is maximum and by which the minimum area of the passage section of the throat 6 is determined for passage through the insulator 7, the diffuser 8 into the combustion chamber 9 of the air flow rate necessary to provide the thrust of the jet nozzle 10 required for the flight of the aircraft. At the same time, in the minimum section of the throat 6, a direct jump is formed, after which in the insulator 7 the air flow becomes subsonic and there are oblique pressure surges closing the direct pressure surge. In the proposed SPAR, as in the prototype, an increased air flow through the minimum passage section of the throat 6 is realized, which allows to reduce the area of the minimum passage section of the throat 6, while the speed of sound in this section is set until the aircraft accelerates to the start speed of the SPVRD, and part of the flow rate of air entering the VZU 3, ~ 20 ÷ 60% is discharged from the braking surface 5 through the holes 13 of the grill 12 through the air duct 17 and the holes 16 of the section 15 into the combustion chamber 9, under the influence of the pressure differential between the inlet pressure into the throat 6 and the pressure in the combustion chamber 9, reduced to the moment of starting the SPVRD, due to the fact that the critical section 11 of the jet nozzle 10 is selected based on the flow of heated gases through the combustion of the fuel in the combustion chamber 9. The dynamic pressure of the air flow discharged through the air duct 17 acts on the shutter 18 (Fig. 1), forming a force that overcomes the oppositely acting force of the spring 23 (Fig. 2) and the shutter 18, turning on the axis 19 in the hinges 20, breaks away from the annular seat 22 and occupies a position near the wall 21 (Fig. 1), opening the passage for the exhaust air flow through the passage section of the annular seat 22 through the air duct 17 through the holes 16 of the portion 15 into the combustion chamber 9. With a further increase in the flight speed of the aircraft by the booster, the degree of increase in the static pressure of the air flow in oblique pressure surges reflected from the braking surfaces 4 and 5 (the degree of compression of the air flow in the VZU 3) increases, therefore, the static pressure and air temperature at the inlet to the throat increase 6. In proportion to the increase in this pressure, the air flow through the windows 13 of the grill 12 and the air flow through the minimum passage section of the throat increase 6. At the same time, with increasing temperatures of air, proportional to the square root of the temperature, the speed of sound in air increases, in the minimum passage section of the throat 6, therefore, the air flow through the throat 6 also increases. With an increase in the speed of air flow through the throat 6, the air flow along the braking surface 5 also increases , which reduces the increase in static air pressure at the inlet to the window 13, which determines the flow rate of air discharged from the braking surface 5. This leads to a redistribution of the initial ratio of the flow rate of air discharged from the braking surface 5 and through the throat 6 (20 ÷ 60% and 80 ÷ 40%), in favor of increasing the percentage of air flow passing through the throat 6. With an increase in air flow to the combustion chamber 9 to a value sufficient to ensure the combustion of fuel in it, the control system 27 activates the fuel system 26 to supply fuel to the combustion chamber 9 and its ignition. If the temperature of the fuel-air mixture is lower than the temperature of self-ignition of the fuel, the control system 27 supplies power to the device 25 for switching on the ignition device 24, which provides ignition of the fuel in the combustion chamber 9 and increases the static pressure of the combustion products in it to a value that ensures the creation of a jet nozzle 10 necessary thrust SPVRD. Due to the increase in the static pressure of the gases in the combustion chamber 9, the pressure drop along the duct path 17 and the airflow discharged through it from the braking surface 5 through the openings 13 of the grill 12 are reduced. Accordingly, the air flow rate and its flow rate through the duct 17 and decreases inversely proportional to the square of the air velocity, the dynamic air pressure decreases, turning the shutter 18 to the open position. In this case, the spring 23 rotates the flap 18 around the axis of rotation 19, pressing the flap 18 against the annular seat 22, and the insignificant air flow through the duct 17 finally stops, and the entire air flow from the VZU 3 through the throat 6 enters the combustion chamber 9, which further increases in it the static gas pressure and thrust of the jet nozzle 10. In the event of a flame failure in the combustion chamber 9 during the evolution of the aircraft, the static air pressure in it decreases sharply, the static pressure drop in the area removed from the surface is 5 can of air holes 13 in plate 12 to the combustion chamber 9 is increased, which leads to a resumption of air flow, bleed from the braking surface 5 of the combustion chamber 9, and start-up cycle SPVRD repeated similarly. The heated air, as a result of compression in the VZU 3, is vented through the air duct 17 of the message through the openings 16 of the portion 15 to the combustion chamber 9, which, unlike the prototype, eliminates the additional heating of the outer wall of the VZU 3. Due to the fact that the gate 18 is at the seat 22 and is preloaded by the spring 23, the air duct 17 is closed, and pressure spikes in the combustion chamber 9 in transition modes (for example, when switching to increased fuel consumption and thrust of the jet nozzle 10) do not affect the operation of the VZU 3, which improves loviya his work and SPVRD in general.

Claims (2)

1. A method of increasing the traction and economic characteristics of a supersonic ramjet engine, including compressing a supersonic air stream flowing into its flow path, with a multi-jump braking surface of the air intake device, supplying air flow through the flow path to the combustion chamber, supplying fuel to the combustion chamber and discharge of fuel combustion products through a jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the air intake device es grating holes and the air duct at low pressure zone of action of the external air flow, characterized in that the diversion of a portion of the air flow is carried out through an opening in the wall of the flow path in the combustion chamber and the entrance portion of the cavity combustion chamber and the nozzle. 2. A method of increasing the traction and economic characteristics of a supersonic ramjet engine, including compressing a supersonic air stream flowing into its flow path, with a multi-jump braking surface of the air intake device, supplying air flow through the flow path to the combustion chamber, supplying fuel to the combustion chamber and discharge of fuel combustion products through a jet nozzle, with the removal of part of the air flow from the braking surface in front of the throat of the air intake device without a lattice of openings and an air duct into the zone of action of reduced pressure of the external air flow, and blocking the air duct with a shut-off device, after increasing the static pressure in the throat of the air intake device, characterized in that a part of the air flow is removed through an opening in the wall of the flow path at the entrance to the combustion chamber and the cavity of the combustion chamber and the jet nozzle, and for the actuation of the device to block the duct use increased static pressure of the air flow at the inlet de into the combustion chamber after ignition of the fuel in it.

Images