KR100776757B1 - Supply apparatus for pulse pressure power of apparatus for stability rating test - Google Patents

Abstract

The pulse pressure wave supply apparatus of the combustion stability evaluation device according to the present invention includes a membrane formed of a honeycomb structure, a pulse gun detonator formed at the rear side of the membrane, and storing a propellant and an initiator, and a rear side of the pulse gun detonator. A pulse gun including an electric supply unit to be mounted; And an induction cavity device having one side connected to the pulse gun and the other side connected to the combustion chamber of the engine. According to the pulse pressure wave supply device of the combustion stability evaluation device as described above, the performance and reliability of the pulse gun is increased to reduce trial and error that may occur during the experiment and to save time and cost.

Pulse Gun, Pressure Wave Induction Device, Rocket Engine

Description

Supply apparatus for pulse pressure power of apparatus for stability rating test

1 is a cross-sectional view of the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus according to an embodiment of the present invention,

2 is a cross-sectional view of the membrane shown in FIG.

3 is a cross-sectional view of a pulse pressure wave supply device of a combustion stability evaluation device showing another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100 ... pulse pressure wave supply 110 ... pulse gun

111 ... Membrane 112 ... Pulse Gun Detonator

113. Electrical supply 120. Guidance device for induction

121 ... Pulse gun pressure wave inlet 122 ... Adapter for pulse gun

123 ... pressure wave regulator 130 ... combustion chamber

The present invention relates to a pulse pressure wave supply device of a combustion stability evaluation device, and more particularly, to a pulse pressure wave supply device of a combustion stability evaluation device, which is an artificial disturbance device used in a combustion stability evaluation test that should be verified when developing a rocket engine. It is about.

The combustion instability of rocket engines occurs during the development of almost all rocket engines and can cause fatal damage to the operation of the engine itself and the entire vehicle system.

Combustion instability is caused by the mutual coupling of the combustion process and the flow field inside the combustion chamber. The energy supplied from the combustion process is known to be caused by amplifying the pressure and the velocity of the flow field inside the combustion chamber.

The most commonly used technique for evaluating the combustion stability of a rocket engine associated with such combustion instability is to create artificial disturbances during the combustion process using a night or pulse gun to determine whether the pressure vibration in the combustion chamber is divergent or attenuated. To evaluate the combustion stability of the engine.

In the case of the pulse gun is installed on the outer wall of the combustion chamber is not directly exposed to the high-temperature, high-pressure combustion gas, because the electrical ignition method is generally used, there is an advantage that can supply artificial disturbance at a desired time during the combustion process.

Accordingly, the pulse gun is the most widely used stability stability technique recently used.

However, the pulse gun technique has a high possibility of getting hot and high pressure gas in the direction of the pulse gun outlet, and has a difficulty in designing and manufacturing a pressure wave of a desired intensity. In addition, since the production cost and the combustion test cost of a single-life rocket engine is quite expensive, it is necessary to sequentially control several pressure waves at a time interval in a single combustion test.

Accordingly, the same applicant has applied for a Korean Patent No. 10-0424792 as a structure for rocket engine combustion stability evaluation.

This provides the method and structure of the pulse gun, which is an artificial disturbance supply device, for the combustion stability evaluation test, which can save time and cost due to trial and error in the development of the rocket engine. Can be developed.

However, the pulse pressure wave supply device of the combustion stability evaluation device as described above, when a plurality of pulse guns are provided, the secondary pulse gun detonation membrane membrane is damaged by the pressure wave generated during the preceding pulse gun detonation due to the membrane of the tightly closed structure. In addition, there arises a problem of scaling the secondary pulse gun pressure wave due to the preceding pulse gun detonation.

In addition, since the pulse supply direction of the pulse gun and the pulse gun pressure wave inflow portion are formed orthogonally, the pressure wave of the pulse gun is not properly supplied to the combustion chamber.

The present invention has been made to solve the above problems, and the pulse pressure of the combustion stability evaluation apparatus whose structure is improved to compensate for the problems of the pulse gun and the induction cavity device used in the combustion stability evaluation test of the rocket engine. The purpose is to provide a wave feeder.

Other objects and advantages of the invention will be described below and will be appreciated by the embodiments of the invention. In addition, the objects and advantages of the invention may be realized by the means and combinations indicated in the claims.

The pulse pressure wave supply device of the combustion stability evaluation device of the present invention for achieving the above object is a membrane formed of a honeycomb structure, a pulse gun detonator formed on the rear side of the membrane, and the drug and initiator are stored; A pulse gun including an electricity supply unit mounted to a rear side of the pulse gun detonator; And an induction cavity having one side connected to the pulse gun and the other side having a pulse gun pressure wave inlet connected to the combustion chamber of the engine.

Here, the membrane is preferably made of aluminum.

In addition, the induction cavity device, a plurality of pulse gun may be connected to supply two or more pressure pulses to the combustion chamber.

In addition, it may be provided between the pulse gun pressure wave inlet and the combustion chamber of the engine, it may be provided with a pressure wave control device for adjusting the pressure wave flowing into the engine from the pulse gun.

Here, the pressure wave control device is preferably a tubular shape having a diameter narrower than the diameter of the pulse gun pressure wave inlet.

Further, it is preferable that the angle formed between the axis of the pulse gun and the axis of the pulse gun pressure wave inlet is an acute angle.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a cross-sectional view of the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the membrane shown in FIG.

First, referring to FIG. 1, the pulse pressure wave supply device 100 of the combustion stability evaluation apparatus includes a pulse gun 110 and an induction cavity device 120.

Specifically, the pulse gun 110 is formed on the membrane 111 formed of a honeycomb structure and the rear side of the membrane 111, the pulse gun detonator 112 and the pulse gun detonator is stored, the pulse gun detonator portion It includes an electrical supply unit 113 mounted on the rear side.

Here, the membrane 111 is installed to a thickness of 1mm of aluminum, and protects the pulse gun detonator 112 from the high temperature, high pressure gas that can be introduced from the combustion chamber 130, the pulse gun 110 The pressure wave detonated in the) acts to flow into the combustion chamber (130).

Furthermore, referring to FIG. 2, 1/3 of the entire thickness of the membrane 111 is formed of a honeycomb structure excellent in increasing structural strength to weight.

When the membrane 111 is applied to the pulse gun 110, the pulse gun 140 waiting for the secondary detonation can be prevented from being detonated at an undesired time by the pressure wave due to the primary detonation. . That is, the secondary detonation pulse gun 140 is not affected by the preceding detonation.

On the other hand, the pulse gun pressure wave inlet 121 of the induction cavity device 120 is formed in a straight tube so that one side is connected to the pulse gun 110, the other side is connected to the combustion chamber 130.

Here, a plurality of pulse gun adapters 122 may be provided around the induction cavity device 120 so that a plurality of pulse guns 110 and 140 having different pressure waves may be connected.

As a result, the pulse pressure wave supply device 100 of the combustion stability evaluation apparatus can sequentially control two or more pressure pulses to the combustion chamber 130 at a time interval.

This saves considerable cost in that the production cost and combustion test cost of a single life rocket engine is quite expensive and a single combustion test can evaluate multiple pressure waves.

On the other hand, according to the experiment, during the combustion process using the conventional induction cavity device, when the pressure of the combustion chamber 130 is 50 bar or more, the magnitude of the pressure wave flowing into the combustion chamber 130 did not exceed a maximum of 10 bar. .

This does not meet the requirements of the combustion stability evaluation test criteria of the rocket engine, and therefore, it is difficult to change or newly manufacture an existing pulse gun structure with a maximum filling amount of 1800 mg to increase the magnitude of the pressure wave.

However, according to the straight pipe induction cavity 120 as described above, when the pressure of the combustion chamber 130 is 50 bar or more, a pressure wave of 25 bar or more is introduced into the combustion chamber 130.

However, in this process, debris of the membrane 111 is generated by the pressure wave when the pulse gun 110 detonates, and damage to the wall surface of the combustion chamber 130 is brought about.

To compensate for this, Figure 3 is a cross-sectional view of the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus showing another embodiment of the present invention.

Referring to the drawings, the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus of FIG. 3 has an acute angle between the axis of the pulse gun 110 and the axis of the pulse gun pressure wave inlet 121. Is formed.

In this case, when the pressure of the combustion chamber 130 is 50 bar or more, the pressure wave flowing into the combustion chamber 130 has a value of 16 bar or more, and at the same time, the damage of the wall of the combustion chamber 130 is also reduced.

Here, in order to introduce the maximum pressure wave into the combustion chamber 130, the angle α formed between the pulse gun 110 and the pulse gun pressure wave inlet 121 is formed in a straight tube shape close to 0 degrees. In order to introduce a minimum pressure wave into the combustion chamber 130, an angle α formed between the pulse gun 110 and the pulse gun pressure wave inlet 121 is formed to be orthogonal to about 90 degrees.

Meanwhile, a pressure wave control device 123 may be provided between the pulse gun pressure wave inlet 121 and the combustion chamber 130.

Here, the pressure wave control device 123 is preferably provided in a tubular shape having a diameter narrower than the diameter of the pulse gun pressure wave inlet 121.

The pressure wave control device 123 as described above can reduce the magnitude of the pressure wave flowing from the pulse gun 110 into the combustion chamber 130 of the engine, so that the pulse gun having a pressure necessary for combustion stability evaluation is separately. There is an advantage that does not need to be produced.

This is effective considering the cost of manufacturing the expensive pulse gun, it is possible to provide the desired pressure without expensive additional costs.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this, The person of ordinary skill in the art to which this invention belongs, Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

As mentioned above, according to the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus of this invention,

First, the honeycomb membrane prevents the detonation of the secondary pulse gun, which can be detonated at an undesired time from the pressure wave generated during the detonation of the primary pulse gun.

Second, the angle formed by the pulse gun pressure wave inlet and the pulse gun is formed at an acute angle so that the pressure wave of the pulse gun sufficiently flows into the combustion chamber, without damaging the wall and the membrane of the combustion chamber.

Third, the pulse gun pressure wave inlet portion is provided with a pressure wave control device does not require the manufacture of a pulse gun having a pressure necessary for the evaluation of combustion stability, thereby reducing the cost.

Claims (6)

A pulse gun including a membrane formed of a honeycomb structure, a pulse gun detonator formed at a rear side of the membrane, and storing an antipsychotic and an initiator, and an electric supply unit mounted at a rear side of the pulse gun detonator; And One side is connected to the pulse gun, and the other side includes an induction cavity having a pulse gun pressure wave inlet connected to the combustion chamber of the engine, Pulse pressure wave supply device of the combustion stability evaluation device, characterized in that it is mounted between the pulse gun pressure wave inlet and the combustion chamber of the engine, the pressure wave control device for adjusting the pressure wave flowing into the engine from the pulse gun . delete The method of claim 1, The induction cavity device, the pulse pressure wave supply apparatus of the combustion stability evaluation apparatus, characterized in that a plurality of pulse guns are connected to supply at least two pressure pulses to the combustion chamber. delete The method of claim 1, The pressure wave control device is a pulse pressure wave supply device of the combustion stability evaluation device, characterized in that the tubular shape having a diameter narrower than the diameter of the pulse gun pressure wave inlet. The method of claim 1, The pulse pressure wave supply device of the combustion stability evaluation apparatus, characterized in that the angle between the axis of the pulse gun and the axis of the pulse gun pressure wave inlet is acute angle.

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