RU2638087C1 - Impulse aerodynamic pipe with electric arc or combined heating of working gas - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: aerodynamic pipe contains an equalization chamber with electrodes, separated from the gas-dynamic channel of the pipe by a diaphragm, and two-stage piston, forming a differential pressure multiplier, the above-piston space of which is connected to the source of the driver gas, a quick-action valve for the start of the stabilization system, contacting the equalization chamber cavity through the piston of the differential pressure multiplier, which contains a device of forced opening of the diaphragm, located at the outlet of the equalization chamber. The piston of the quick-action valve is made in the form of a glass, the open part of which faces the cavity with the locking pressure and the closed blind part of which locks the hole for the driver gas feed to the above-piston space of the pressure multiplier, while the high-pressure channel, connecting the piston with the rod to the equalization chamber cavity, is filled with a fluid and closed with the piston on the side of the equalization chamber, and the device for forced opening of the diaphragm is additionally equipped with an external electric circuit of the diaphragm opening control and contains the pneumatic mechanical lock, associated with the equalization chamber, that gives permission to open the diaphragm only when the pressure in the equalization chamber increases in heat supply.

EFFECT: increased reliability and safety in the operation of short-term impulse aerodynamic pipes.

3 dwg

Description

The invention relates to the field of experimental aerodynamics and can be used to prevent accidents in high-enthalpy installations of short duration equipped with a stabilization system for flow parameters, both with electric arc and with combined heating of the working gas (arc + chemical energy).

To obtain a working gas with extremely high flow braking parameters (P ₀ up to 2000 bar, T ₀ up to 4000 K), various aerodynamic installations of short duration are used. These include pulsed wind tunnels [1, 2, 3], where the gas in the prechamber is heated by an electric arc at a constant density, as well as short-lived wind tunnels [4, 5] with an electric arc discharge.

All of these installations are characterized by a high level of technical complexity, operational danger due to possible malfunctions in the control of technological processes, since after the installation is launched, human participation in further operations is excluded. As examples, we can consider some of the disadvantages characteristic of such pipes.

For impulse pipes [1-3], as well as for wind tunnels with electric arc heating of short duration [4, 5], the absence of an electric arc discharge due to a technical malfunction at the start of the installation will trigger the differential multiplier and increase the pressure in the prechamber due to the movement of the multiplier , rupture of the diaphragm and, accordingly, to spontaneous breakdown between the electrodes at the stage of expiration of the working gas through the critical section. As a result, a prechamber with a pressure multiplier will fail.

There may be other emergency pipe conditions associated with premature opening of the diaphragm. For example, after charging the capacitor bank when you press the start button, the discharge of the capacitor bank for some technical reason does not occur, but the signal passes to undermine the controlled diaphragm. The diaphragm is opened, the pressure in the prechamber drops to vacuum and a spontaneous discharge of the battery occurs. This emergency option permanently incapacitates the wind tunnel up to the manufacture of new components: pistons, prechambers, etc.

The closest known solution to the claimed technical solution is a pulsed wind tunnel [3]. The installation comprises a discharge chamber (prechamber) with coaxial electrodes, which is separated from the rest of the gas-dynamic path of the pipe by a diaphragm with a controlled opening. The small stage of the multiplier piston contains a high-pressure channel, which ends with a piston with a rod designed to open a high-speed valve (BC). When the BC is opened, pushing gas is supplied from the receiver to the over-piston space of the large stage of the piston of the pressure multiplier. The control system of the BK operation includes an electromagnetic valve for dumping gas from the cavity, which locks the BK piston, a manometer and a gas supply valve to the cavity for locking by the piston the gas inlet opening in the above-piston space of the large stage of the pressure multiplier piston.

Before starting the pipe, the minimum pressure is set in the cavity of the pressure regulator, which is necessary for the piston to close the hole for supplying pushing gas to the over-piston space of the pressure multiplier. The value of the minimum pressure can be different and is associated with the initial gas pressure in the tube chamber and the pressure of the pushing gas. At the start of the installation, the pressure in the prechamber sharply rises, the pressure in the prechamber through the high pressure channel is transmitted to the piston with a rod, which, under the influence of excessive force, displaces the piston BC, thereby opening up the access of pushing gas into the cavity in front of the large piston stage. The pressure in the cavity in front of the large piston increases sharply and finally opens the hole by displacing the piston BK to the extreme position to the stop. In this case, a significant increase in the locking pressure occurs in the relatively small cavity G between the piston of the piston cylinder and the rear wall of the valve, which can lead to a violation of the operating mode of the cylinder (reciprocating piston movement mode). To ensure the normal operating mode of the BC, this cavity is connected through an air duct to an electromagnetic valve, which opens at the moment the pipe is launched and relieves excess pressure into the atmosphere.

When using the combined heating of the working gas (arc + chemical energy), the essence of the controlled diaphragm is the possibility of delaying the opening so that the reaction in the prechamber passes completely. This time is in the range from one to several tens of milliseconds. After the specified time, a signal is opened to open the diaphragm.

The disadvantages of these technical solutions with electric arc or electric arc + chemical heating is that in this circuit of a pulsed wind tunnel there are no measures to ensure the safety of its operation, since the inclusion of an electromagnetic valve to relieve pressure from the cavity G at the time of starting the pipe in all situations in the absence of an arc discharge will cause an accident. When a small step of the multiplier piston passes by the electrodes (there was no electric discharge when the pipe was started), an electric arc discharge will occur between the positive electrode and the piston and the prechamber with other systems will fail.

A similar emergency situation can occur in the absence of discharge of the capacitor bank and opening according to the signal of the controlled diaphragm. The pressure in the prechamber will drop to vacuum, the battery will discharge in vacuum with all the unpleasant consequences.

The objective of the proposed technical solution is to increase the reliability and safety during operation of pulsed short-lived wind tunnels with electric arc or combined heating of the working gas, to expand the experimental capabilities of the short-lived wind tunnel by increasing the range of realizable flow braking parameters by using various sources of heating of the working gas and stabilization of flow parameters during operating mode.

The use of the invention will ensure reliability and trouble-free operation of critical systems of a pulsed wind tunnel at any heat supply modes in the prechamber, prevent possible emergency situations, increase the performance of the wind tunnel.

The problem is achieved in that a pulsed wind tunnel with an electric arc or combined heating of the working gas contains a prechamber with electrodes separated from the gas dynamic path of the pipe by a diaphragm, and a two-stage piston forming a differential pressure multiplier, the over-piston space of which is connected to the source of the pushing gas, a quick-acting valve for starting the system stabilization in contact through the piston of the differential pressure multiplier with the cavity of the prechamber, which contains a device for forced opening of the diaphragm located at the outlet of the prechamber, while the high-speed valve is connected to the pneumatic valve with a manometer and an electromagnetic valve, and the piston of the differential pressure multiplier contains a feedback system made in the form of a high-pressure channel, one end of the housing of which is fixedly mounted at the end of the small piston stage, and the second is connected to the piston with a rod, which interacts with the piston of the high-speed valve, and the device itelnogo opening aperture comprises a housing with a piston, wherein the piston facing the diaphragm, and equipped with a knife is driven by a second piston which is acted upon with a pyrotechnical blasting apparatus, a condenser and a battery charger. According to the invention, the piston of the quick-acting valve is hollow in the form of a cup, the open part of which is facing the cavity with locking pressure, and the closed (deaf) part locks the push gas supply hole into the over-piston space of the pressure multiplier, while the high-pressure channel connecting the piston with the rod with the cavity prechamber, filled with liquid and closed by a piston on the prechamber side, and the aperture forced opening device is additionally equipped with an external tamper control circuit diaphragm and contains a pneumomechanical lock associated with the prechamber, which gives permission to open the diaphragm only with an increase in pressure in the prechamber due to heat supply.

The listed features are not identified in other technical solutions when studying the level of this technical field and, therefore, the technical solution is new.

In FIG. 1 shows a diagram of a pulsed wind tunnel with an electric arc or combined heating of a working gas with stabilization of flow parameters; in FIG. 2 is a diagram of a device for triggering a differential pressure multiplier and a high-speed valve for launching a stabilization system, which ensure trouble-free operation of the pipe, FIG. 3 - a device for the forced opening of the diaphragm with an external electric circuit for controlling the opening of the diaphragm, containing a pneumomechanical lock.

The main structural elements of a pulsed wind tunnel with an electric arc or combined heating of the working gas with stabilization of flow parameters are: chamber 1, which includes coaxial electrodes of capacitor bank C. Chamber 1 is limited on one side by a diaphragm 2 with a forced opening device, and on the other hand, by an end face small stage 3 two-stage piston pressure multiplier.

The two-stage piston contains a feedback system (Fig. 2), which consists of a high-pressure channel 4 filled with liquid, and two pistons - the piston 5 contacts the chamber B of the prechamber, and the piston 6 contacts the piston 7 with the piston 8 of the high-speed valve 9. Hollow the piston 8 is made in the form of a glass with a blank bottom.

The rod 7 in the pre-start state of the wind tunnel through the cavity B of the pressure multiplier housing is in contact with the piston 8 of the high-speed valve 9. The piston 8 is placed in the cylinder 10 coaxially with the body of the high-speed valve 9 and forms an annular channel D with an external casing. Through the annular channel D pushing gas from the receiver 11 through the through cylindrical channel 12 (Fig. 1) is supplied to the above-piston space B of the pressure multiplier. Between the end face of the cylinder 10 and the hollow piston 8, a cavity G is formed, connected with the air bag 13, the pressure gauge 14, the valve 15 and the electromagnetic valve 16.

The device for opening the diaphragm 2 is additionally equipped with an external electric circuit for controlling the opening of the diaphragm and contains a pneumomechanical lock associated with the cavity B of the prechamber, which gives permission to open the diaphragm 2 only with heat supply and an increase in pressure in the prechamber.

The device for opening the diaphragm and the diaphragm 2 separate the chamber B of the prechamber from the rest of the gas-dynamic path of the wind tunnel. The device (Fig. 3) consists of a housing 17 with pistons 18, 19 and a fluid between them, while the piston 18 facing the diaphragm 2 is equipped with a knife 20 and is driven by the piston 19 through the fluid after blasting the igniter 21. The knife 20 has a square cross sections with three cutting edges. The fourth edge is deepened inside the knife and does not participate in the opening of the diaphragm.

The external diaphragm opening control circuit, in addition to the computer 22, the high-voltage transformer 23, the key 24 (IFP lamp) and the capacitor bank C, additionally contains a pneumomechanical lock 25 (external feedback control system of the diaphragm opening) connected to the cavity B of the prechamber, which gives permission to opening of the diaphragm 2 only with heat supply and pressure increase in the prechamber.

In the presence of heat supply in the prechamber and an increase in pressure, the electric control circuit for the destruction of the diaphragm closes, allowing the signal from the computer 22 to open the diaphragm.

Pulse wind tunnel with electric arc or combined heating of the working gas works as follows.

Before the experiment, the cavity B of the prechamber is isolated from the gas-dynamic path of the pipe by a diaphragm 2 with a forced opening device. Locking pressure is supplied to cavity G by valve 15. The magnitude of this pressure depends on the initial pressure in the prechamber and the pressure in the receiver 11 with the pushing gas. The receiver with the pushing gas is filled with compressed air, and the prechamber with air or a mixture of gases. The capacitor bank C is being charged.

When the wind tunnel starts (the discharge time of the capacitor bank is ~ 1 ms), the temperature and pressure of the working gas increase in cavity B of the prechamber. This pressure through the piston 5, the liquid in the high-pressure channel 4 and the piston 6 with the rod 7 acts on the piston 8 of the high-speed valve 9 and moves the piston 8 to the left, thereby opening up the access of the pushing gas to the over-piston space B of the pressure multiplier. The pressure in the cavity increases sharply and finally moves the piston 8 of the high-speed valve 9 to the extreme left position. The piston system of the pressure multiplier begins to move and moves to the right towards the prechamber. Since there is no high voltage at the positive electrode of the capacitor bank C after discharge, the normal operation mode of the wind tunnel is implemented. If for some reason the battery does not discharge, there will be no increase in pressure in the prechamber, the high-speed valve 9 of the flow stabilization system will not open, and the diaphragm 2 will not open due to the open tamper control circuit, thus preventing an accident at the installation .

A positive effect is achieved thanks to the constructive solutions of the main components of the pulsed wind tunnel, ensuring the safety of the pipe, namely the nodes of the feedback feedback system of the inclusion of the pressure multiplier and the nodes of the diaphragm opening control system, the functioning of which is determined by the presence of pressure increase in the prechamber when the wind tunnel starts.

Information sources

1. US patent No. 3418445, CL. 73 - 147, 1968.

2. USSR copyright certificate No. 1156462, G01M 9/00.

3. RF patent No. 2439523, IPC G01M 9/02 - prototype.

4. RF patent No. 2436058, IPC G01M 9/02.

5. RF patent No. 2578052, IPC G01M 9/00.

Claims (1)

A pulsed wind tunnel with an electric arc or combined heating of the working gas, containing a prechamber with electrodes, separated from the gas dynamic path of the pipe by a diaphragm, and a two-stage piston forming a differential pressure multiplier, the over-piston space of which is connected to the push gas source, a quick-acting stabilization system starting valve that contacts through the piston differential pressure multiplier with a pre-chamber cavity that contains the device will force a full opening of the diaphragm located at the outlet of the prechamber, while the high-speed valve is connected to the pneumatic valve with a manometer and an electromagnetic valve, and the piston of the differential pressure multiplier contains a feedback system made in the form of a high-pressure channel, one end of the housing of which is fixedly fixed to the small end the piston stage, and the second is connected to the piston with a rod, which interacts with the piston of the high-speed valve, and the device for the forced opening of the diaphragm contains t the case with pistons, while the piston facing the diaphragm is equipped with a knife and is driven by a second piston, which is affected by a blasting device with a squib, capacitor and charger, characterized in that the piston of the quick-acting valve is made hollow in the form of a cup, the open part which faces the cavity with locking pressure, and the closed blind part locks the hole for supplying pushing gas into the over-piston space of the pressure multiplier, while the high pressure channel connecting the shaft with a stem with a prechamber cavity is filled with liquid and closed by a piston on the prechamber side, and the diaphragm forced opening device is additionally equipped with an external diaphragm opening control circuit and contains a pneumomechanical lock associated with the prechamber, which gives permission to open the diaphragm only when the pressure in the prechamber increases heat supply.

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