RU71434U1 - GAS-DYNAMIC INSTALLATION - Google Patents

Abstract

A useful model, a gas-dynamic installation, relates to the field of hypersonic aerodynamics and radiation plasma dynamics, in particular, to the technique associated with the production of hot plasma in the study of physical processes in hypersonic wind tunnels. The technical result, the claimed utility model is aimed at achieving, consists in constructing a system of hypersonic aerodynamics for studying a high-temperature plasma flow in a free molecular flow. Gas-dynamic installation, including a hypersonic wind tunnel (GAT), in which a high-pressure gas cylinder, a regulating throttle, an electric arc heater, a metering device, a primary supersonic nozzle, a magnetohydrodynamic (MHD) accelerator with control windings, a secondary nozzle, and a working part of the GAT with the investigated model of the aircraft (LA), the output nozzle, the vacuum tank, and a digital computer (digital computer), connected by inputs through electric converters of signals with an ion probe, with control electric windings of the MHD accelerator and electric arc heater, the installation of electron-cyclotron resonant plasma heating based on a gyrotron with a power source and a control system connected through a converter of electrical signals to the input of a digital computer, a quasi-optical path consisting of copper mirrors with cylindrical surfaces, optically connecting a branch pipe of the GAT region in front of the MHD accelerator with a gyrotron, and a millimeter-wave interferometer using the radiation source — a laser, mirrors, two detectors, a phase meter, and the plasma arm of the optical line of the interferometer passes through the working part of the GAT to the first detector, and the reference arm passes through the delay line to the second detector, the outputs of which are connected to the inputs of the phase meter, the output of which is through the converter electrical signals connected to the input of the computer.

Description

A useful model - a gas-dynamic installation relates to the field of hypersonic aerodynamics and radiation plasma dynamics, in particular, to the technique associated with the production of hot plasma in the study of physical processes in hypersonic wind tunnels.

A large-sized hypersonic wind tunnel (GAT) T-117 is known (see G.S. Byushgens, E.L. Berdzhitsky, TsAGI - Center for Aviation Science, M. "Science", 1993), which allows the study of aerodynamic and thermal characteristics of models of various hypersonic aircraft with a fairly complete geometric similarity of models and nature. The aerodynamic circuit of the T-117 pipe includes an electric arc heater, the working part is a круг 1 m circle, a heat exchanger, a vacuum tank, shut-off valves, ejectors, a supersonic nozzle, and a supersonic diffuser.

The T-117 hypersonic pipe is a batch pipe using high-pressure compressed air accumulated in cylinders with a capacity of 10 m ³ each.

The necessary degree of compression in the pipe is created, on the one hand, by high braking pressure in the tube chamber (from 40 to 280 atm.) And, on the other hand, by using a four-stage system of ejectors or a vacuum tank with a volume of 3000 m ³ with an initial discharge of up to 0.01 mm Hg, creating the necessary vacuum for one of the three unregulated diffusers.

The pipe has a set of profile axisymmetric supersonic nozzles with an output diameter of 1.0 m, designed to realize the numbers M at the nozzle exit in the range from 10 to 20. The range of Re numbers is from 0.15 · 10 ⁶ to 4.8 · 10 ⁶ (referred to 1 m).

To prevent air condensation in the working part when it is accelerated to given supersonic speeds, the working gas is pre-heated to a temperature in the prechamber of 1200-2000K using an electric arc heater with a capacity of 25,000 kW.

The working part of the pipe is made according to the scheme of the Eiffel chamber with cooled walls and is equipped with two high-speed mechanisms for introducing the tested model into the stream.

The pipe is equipped with a high-speed measuring and information complex consisting of: tensometric scales for various cases of model loading, pressure and temperature sensors, optical flow visualization tools, information collection and processing systems using computer technology. The experiment process is automated. The output is given in the form of tables and graphs. The following types of experiments can be carried out in a T-117 hypersonic wind tunnel:

- determination of the total aerodynamic characteristics of aircraft models and their elements;

- determination of the distribution of pressure and heat fluxes on the surface of the models;

- visualization of the flow pattern using a shear interferometer;

- physical research.

However, the composition and capabilities of this experimental base do not reflect the peculiarities of the hypersonic range of flight speeds — the inability to simulate the free molecular nonequilibrium flow of a high-temperature plasma under ground conditions.

The well-known gas-dynamic installation, V.I. Vinogradov, J. Vernier, M.A. Karakin, N.P. Filippov et al., "Experimental modeling of collisionless shock waves at the" plasma focus "installation, Russian Research Center," Kurchatov Institute ", 2003 g.

The experiments were performed on the Plasma Focus (PF) setup.

The amplitude of the discharge current is 3 MA, the working gas is neon at a pressure of 0.5-1 Torr. A porcelain cylinder with a diameter of 40 cm and a height of 40 cm is mounted on the top cover of the PF discharge chamber to study the interaction of plasma flows with a magnetic field. Various systems were used to create a transverse magnetic field: based on electromagnets (B = 0- ± 500 G) and based on rare-earth magnets (B = 2500 G). Optical spectroscopy methods were used to determine the density and temperature of the background plasma and plasma flow. To determine the shape of the plasma stream, as well as its velocity in the interaction region, photoelectronic amplifiers (PMTs) with horizontal and vertical slits were used. The main method for determining the average flow velocity at the span base was collimated light probes. The readings of two light probes spaced a short distance were also used to determine the instantaneous velocity in the interaction region.

The experimental conditions on the PF made it possible to ensure a collisionless motion of plasma flows with a velocity of ~ 10 ⁷ cm / s.

However, the PF installation does not make it possible to carry out studies and modeling of the processes of high-temperature plasma flow around aircraft models due to the limited numbers M and the time of the experiment.

Known hyper-velocity ADT with magneto-gas-dynamic accelerator Faraday air flow (see G.S.Byushgens, V.V. Sychev, E.L. Berdzhitsky and others, TsAGI - the main stages of scientific activity 1968-1993, p. 396), taken for the prototype. ADT contains a sequentially located electric arc heater, a metering device, a primary supersonic nozzle, a magnetogasdynamic accelerator, a secondary nozzle, a working part, and ejectors.

The output section of the secondary nozzle is 0.025 × 0.025-0.1 × 0.18 m, the flow velocity is up to 8 km / s.

However, this setup does not allow creating a physical model of the flow around bodies in a nonequilibrium discharged high-temperature gas medium. This method is not suitable for measurements in boundary hypersonic flows. The method of plasma heating - Joule heating - is not effective at high plasma temperatures, because the collision frequency between electrons and plasma ions, which determines the energy release, decreases with increasing temperature as T ^3/2 .

The technical result, the claimed utility model is aimed at achieving, consists in constructing a system of hypersonic aerodynamics for studying a high-temperature plasma flow in a free molecular flow.

Essential features.

To obtain the specified technical result in a gas-dynamic installation (GU), which includes a hypersonic wind tunnel (GAT), in which a cylinder with a high air pressure, a regulating throttle, an electric arc heater, a metering device, a primary supersonic nozzle, a magnetohydrodynamic (MHD) accelerator with control electric windings, a secondary nozzle, the working part of the GAT with the investigated model of the aircraft (LA), the output nozzle, the vacuum tank, and digital subtraction a compression machine (CVM) connected to the inputs through the converters of electrical signals with an ion probe, with the control electric windings of the MHD accelerator and electric arc heater, the installation of electron-cyclotron resonant plasma heating based on a gyrotron with a power source and a control system connected via an electrical signal converter to computer input, a quasi-optical path consisting of copper mirrors with cylindrical surfaces,

optically connecting a branch pipe of the GAT region in front of the MHD accelerator with a gyrotron, and a millimeter-wave interferometer with a radiation source - a laser, mirrors, two detectors, a phase meter, while the plasma arm of the optical line of the interferometer passes through the working part of the GAT to the first detector, and the reference arm - through a delay line to the second detector, the outputs of which are connected to the inputs of the phase meter, the output of which through the converter of electrical signals is connected to the input of the digital computer.

The list of figures in the drawings.

To clarify the essence of the utility model, figure 1 shows a functional diagram of a gas-dynamic installation, which shows:

1 - cylinder with high pressure;

2 - regulating throttle;

3 - electric arc heater with control electric windings;

4 - dosing device, shut-off valve;

5 - primary supersonic nozzle;

6 - magnetohydrodynamic (MHD) Faraday accelerator with control electric windings - 7;

8 - secondary nozzle;

9 - working part of a hypersonic wind tunnel;

10 - holder for the suspension model LA;

11 - model of the aircraft;

12 - output nozzle;

13 - vacuum container;

14-gyrotron;

15-ion probe;

16, 17, 18, 19, 45 - converter of electrical signals;

20 - digital computer (digital computer);

21 - radiation source (laser);

22, 24, 27, 30 - a mirror;

23, 25, 28, 29, 31 — translucent mirror — quartz plates;

26 - optical delay line;

32, 34 - detector;

33 - phase meter;

35 - electrical windings of the gyrotron;

36 - adiabatic gun;

37 - narrowing of the waveguide;

38 - waveguide;

39 - collector;

40 - output window for outputting microwave radiation, waveguide;

41, 42 - copper mirrors;

43 - pipe input radiation in the GAT, a dielectric window;

44 - electrical windings create double-helical fields. Figure 2 shows the countdown of the phase incursion D ₁ -D ₂ in the plasma and reference arms of the interferometer.

The gas-dynamic installation includes a GAT, in which a cylinder with a high air pressure 1, a regulating throttle 2, an electric arc heater 3 with control electric windings, a metering device 4, a primary supersonic nozzle 5, a magnetohydrodynamic accelerator 6 with control electric windings 7, a secondary nozzle 8, are arranged in series working part 9 GAT with the investigated model of LA 11, mounted on a holder 10, the output nozzle 12 and the vacuum tank 13, and a digital computer (digital computer) 20 connected to the input through electrical signal converters 17, 18, 19 with an ion probe 15, with control electric windings of the MHD accelerator 7 and the arc heater 3. The installation of electron-cyclotron resonant plasma heating based on gyrotron 14 with a power source and a control system connected through an electrical signal converter

16 to the input of the digital computer, a quasi-optical path consisting of copper mirrors 41, 42 with cylindrical surfaces, optically connecting the nozzle 43 of the GAT region in front of the MHD accelerator 6 with the gyrotron 14, and a millimeter-wave interferometer with a radiation source - laser 21, mirrors 22, 24, 27, 30, translucent mirrors 23, 25, 28, 29, 31, two detectors 32, 34, a phase meter 33. The interferometer is used for plasma diagnostics and has two optical arms. In this case, the plasma arm passes through the working part of the GAT to the detector 34, and the reference arm passes through the delay line 26 to the detector 32. The outputs of the detectors 32 and 34 are connected to the inputs of the phase meter 33. The output of the phase meter 33 through the electrical signal converter 45 is connected to the input of the digital computer 20.

Gas-dynamic installation operates as follows. Simulation of hypersonic flight requires reproducing in the GAT braking pressures from fractions up to hundreds of MPa and braking temperatures up to 10 ⁴ K. At hypersonic Mach numbers, the total pressure losses during flow braking intensively increase and, accordingly, the required pressure drops in the GAT. At Mach numbers> 4.5, the air in the GAT must be heated to prevent its condensation, so at M = 10-heat up to 10 ³ K, at M = 20 up to (2.5 ÷ 2.8) -10 ³ K. Maximum pressure in GAT with an electric arc heater 3 is equal to 18-20 MPa, which allows you to simulate the flight of hypersonic aircraft (LA) only at high altitudes. At high altitudes, a large pressure drop is ensured by using a vacuum vessel 13. Condensation of the main components of the air is eliminated by the electric arc heater 3 of the working gas, in which an external magnetic field is used to stabilize the discharge.

The interaction of the flows in the GAT is realized by changing the speed of the plasma flow in the MHD accelerator 6. This process is controlled by the digital computer 20, which is connected through the converter of electrical signals 19 to the electrical windings 7 of the MHD accelerator 6, through the converter

electrical signals 17 - with the electric windings of the electric arc heater 3, and through an electrical signal converter 18 is connected to the ion probe 15. The ion probe 15 is used to determine the concentration and temperature of the electrons by measuring the current flowing to the electrodes immersed in the plasma with various supplied to it voltages. Structurally, the ion probe 15 is made in the form of separate sensors or combs for measuring the ion concentration profile.

Further plasma heating — the process of transferring the energy of external sources to the energy of the chaotic motion of plasma particles — occurs using electron cyclotron resonance heating (ECRN).

ECRN is based on the proximity of the frequency of the electromagnetic wave ω to the electron cyclotron frequency ω _c (or its harmonic), which corresponds to electromagnetic waves 1-2 mm long. ECRN allows you to control the distribution of heating power over the plasma cross section. The use of a powerful ECRS in open volumes makes it possible to create “suprathermal” electrons in them, which is necessary for the functioning of thermal barriers in them. In ECRN, cyclotron waves - periodic perturbations of the space charge density, as well as the stationary trajectory and velocity of electrons propagating in an electron beam in a longitudinal magnetic field, arise as a result of a periodic change in the electron velocity component perpendicular to the magnetic field under the action of external forces in any flow section . The transfer of perturbations occurs as a result of the movement of electrons with a velocity V _e along the magnetic field with simultaneous rotational motion with a cyclotron frequency ω _c . The phase velocity of the cyclotron wave is equal to V _f = V _e (1 ± ω _c / ω), where ω is the frequency of periodic disturbances (± fast or slow waves).

Cyclotron resonance is the selective action of a microwave electromagnetic field with charged particles moving in a constant magnetic field, accompanied by a sharp increase or decrease in particle energy. In a plane perpendicular to the lines of force of the magnetic field, the particle (in the presence of the transverse component of the velocity) performs periodic motion along a circular path under the action of the Lorentz force. The cyclotron frequency is ω _c = QB / m, where Q is the charge, m is the mass of the particle, and B is the magnetic induction of the field. The cyclotron resonance phenomenon occurs at an electromagnetic field frequency equal to or a multiple of ω _c . In GU two-start helical fields are applied. An increase in plasma pressure in such a magnetic configuration leads to the appearance of a magnetic well and, accordingly, to an improvement in plasma stability. The magnetic field strength on the axis B ₀ ≥1.5 T. The two-way winding makes N = 5 ÷ 7 steps at a given length of GAT. The absorption of a high-frequency beam in a GAT plasma in the presence of a cyclotron resonance, in the case of a sufficiently hot plasma, manifests itself in the form of a noticeable fraction of the input power even at a single passage of the beam through the plasma. The pulses of the gyrotron 14 do not exceed 8-10 ms, and are determined by the time constant of the GAT magnetic field. The electrical windings 35 are powered by a quasi-sinusoidal half-wave current capacitor bank with a total duration of 90 ms.

The ECRN of a currentless plasma is connected using the second harmonic of the electron cyclotron frequency (ECH) of the gyrotron with a frequency equal to f ₀ = 75 GHz. The absorption by the plasma of the wave at the second harmonic (ECH) occurs at a single-pass absorption coefficient. The complete formation of the plasma cord ends 1.5 ms after the microwave pulse is turned on, and the main increase in density occurs over a time of the order of 0.5 ms. The choice of the amplitude, duration and moment of switching on the power pulse of the piezocrystalline valve of the inlet of the working gas of the metering device 4 maintains a constant plasma

total heating pulse. By the time the microwave heating pulse is turned off, enough energy has been accumulated in the electronic component to maintain an effective ionization process for the gas entering the plasma.

When the microwave is turned on, a gas breakdown occurs and a very rapid (within 0.1-1.2 ms) formation of the plasma density occurs, then heating with reaching the stationary values of the main plasma parameters. The dependence of heating on the magnitude of the magnetic field is of pronounced resonance character.

Gyrotron 14 is a cyclotron resonance maser (MCR), an microwave electric vacuum device, whose operation is based on the interaction of a stream of electrons moving in a constant magnetic field along helical paths with high-frequency fields of resonators and waveguides at frequencies close to the cyclotron frequency of electrons. The amplification of electromagnetic waves in the ICR is carried out by means of induced radiation, and coherent microwave oscillations are obtained from the ensemble of electrons rotating with a cyclotron frequency. In an electron flow with helical trajectories under the action of an electromagnetic wave with a frequency ω close to the cyclotron frequency of electrons ω _c = eH ₀ c / ε (where is the electron energy, m ₀ , e, V _e is the rest mass, charge and speed of the electron, respectively, c is the speed of light, Н ₀ is the intensity of a uniform static magnetic field), an electron bunch (transverse) with respect to the magnetic field arises relativistic dependence of cyclotron frequency on electron energy. Radiation of the resulting clumps leads to amplification of the wave.

The electron beam in the gyrotron 14 is formed using an adiabatic gun 36 (AP), which serves to form a tubular electron beam with helical electron paths and a small electron velocity spread. AP 36 contains asymmetric

a cathode and anode having the shape of truncated cones and located in the growing edge field of the solenoid. In AP 36, electrons emitted from the cathode under the influence of crossed electric and magnetic fields acquire oscillatory (oscillatory) motion and angular drift, and under the action of the longitudinal component of the electric field, they shift along the axis. As the electrons move in the axial direction, the electric field and angular drift decrease and the electron paths are converted into helical lines. Gyrotron 14 contains a waveguide 38 in the form of a sufficiently long (compared to the working wavelength) segment of a metal pipe with constrictions 37 at the ends (open resonator); behind the constrictions, the pipe expands smoothly towards the cathode and collector 39. The microwave power output from the interaction space is due to the fact that the pipe narrowing from the collector 39 is less than from the cathode. In this case, the power from the interaction space “seeps” towards the collector 39, the functions of which are performed by another (output) waveguide 40. The dielectric microwave energy output window is located in the output waveguide 40 behind the collector.

High-frequency power is transported from the gyrotron to the camera using a quasi-optical path consisting of two copper mirrors 41, 42. To focus the microwave beam, the mirrors have cylindrical surfaces pairwise oriented in perpendicular planes.

Sounding a plasma as a macroscopic medium affecting the propagation of an electromagnetic wave makes it possible to determine the plasma density n _e and the collision frequency of electrons with heavy particles ν _e . The dependence of the dielectric constant of the plasma on the frequency is expressed as:

n _c = mω ² / 4πe ² is the critical concentration at which ω = ω _p (where ω _p is the resonant frequency) and Reε = 0. For ω> ω _{p, the} signal passes through the plasma; for ω <ω _p , waves are reflected.

The interferometric method for studying unsteady plasma is based on the dependence of the phase difference between the reference radiation and the radiation transmitted through the plasma on the plasma density. If the plasma density n _e <n _s and the wavelength λ≪Λ is the characteristic size of the inhomogeneity, then R _e ε determines the phase difference of the wave transmitted through the plasma and the reference one:

where L is the probe length. The imaginary part ε determines the exponential attenuation of the wave with the coefficient , then ν _{e is} calculated.

Diagnostics of plasma density is carried out using a single-channel 2-mm interferometer. The sounding of the plasma by millimeter and submillimeter waves makes it possible, on the basis of interferometric measurements, to determine the electron concentration in a wide range of 10 ¹² -10 ¹⁶ cm ^-3 and to observe its change with the required temporal resolution (at L = 20 cm, the probing path length). The probe wave is introduced into the plasma and its reception is carried out using a beam radiation source, the dimensions of which are determined from the condition that the region of the localized wave in the plasma is significantly smaller than the plasma size. The polarization of the excited wave should be parallel to the magnetic field, and the propagation direction should be perpendicular to the field. The angular divergence of the excited wave is small enough to satisfy the quasiperpendicular propagation condition.

In the interferometric scheme, an indication of a time-varying phase incursion is carried out, Fig.2. Projected

the interference signal of the detector 32 allows you to determine the change in phase incursion by the position of the maxima or minima (the distance between them corresponds to a change in Δφ by π). When indicating the distinction is made between the sign of the phase and amplitude of the signal, fluctuation in concentration.

The scheme is based on the use of sawtooth modulation of the phase difference between the plasma and reference channels of the interferometer with a “saw” period much shorter than the characteristic time of the change in electron concentration. It is carried out by modulating the frequency of the generator, which turns into phase modulation in the presence of a stroke difference in the plasma and reference arms. The necessary path difference (creating a modulation of the phase difference exceeding the measured phase shift) is achieved by introducing into one of the arms of the interferometer an optical delay line 26, which provides a delay of electromagnetic signals for a predetermined period of time. The interference signal at the detector 32 allows you to compare the changes in the phase of the wave in the plasma with the change caused by the modulation of the phase within each period of the sawtooth oscillations. This comparison is carried out in the phasemeter 33 by determining the frequency shift, figure 2. Mixing waves with a shifted frequency results in the separation of a differential low frequency signal. The phase shift between the reference wave and the wave transmitted through the plasma is determined in this case by the time shift of the zeros of the interference signal. A laser 21 was used as a source on the transition of molecules between vibrational and rotational levels λ = 330 μm, P = 150 mV. The rays are separated using quartz plates 23, 25, 28, 29, 31. Reflectors and focusing elements are made of aluminized glass mirrors 22, 24, 27, 30. The detection in 32, 34 is carried out by piezoelectric elements, the phase shift is found by the time shift of the minimum detected signals with an error of 10 ^-2 . The phasometer 33 measures the phase angle between the electric voltage vectors acting in the electrical circuit. Electronic circuit of it,

using the indications of two batch processes, the electrical quantities of which determine a measurable ratio; creates a state of synchronism. The phase shift signals coming from the phase meter 33 through the electrical signal converter 45 are transmitted to the input of the digital computer 20.

Claims (1)

Gas-dynamic installation, including a hypersonic wind tunnel (GAT), in which a high-pressure gas cylinder, a regulating throttle, an electric arc heater, a metering device, a primary supersonic nozzle, a magnetohydrodynamic (MHD) accelerator with control windings, a secondary nozzle, and a working part of the GAT with the investigated model of the aircraft (LA), the output nozzle, the vacuum tank, and a digital computer (digital computer), connected by inputs through electric converters signals with an ion probe, with control electric windings of the MHD accelerator and electric arc heater, characterized in that the installation of electron-cyclotron resonant plasma heating based on a gyrotron with a power source and a control system connected through an electric signal converter to the input of the digital computer is introduced into it, a quasi-optical path, consisting of copper mirrors with cylindrical surfaces, optically connecting the branch pipe of the GAT region in front of the MHD accelerator with a gyrotron, and the interferometer is mil of the measuring range with a radiation source - a laser, mirrors, two detectors, a phase meter, while the plasma arm of the optical line of the interferometer passes through the working part of the GAT to the first detector, and the reference arm - through the delay line to the second detector, the outputs of which are connected to the inputs of the phase meter, output which, through an electrical signal converter, is connected to the input of a digital computer.