KR20040009468A - The apparatus for airtight test of fluid fuel rocket engine - Google Patents

Abstract

PURPOSE: An apparatus for airtightness test is provided to reduce the size and weight of the apparatus, while allowing for ease of attachment/detachment of airtightness plate and airtightness test. CONSTITUTION: An apparatus for airtightness test comprises a support shaft(51) disposed at the center of a nozzle(100) of a rocket; an airtightness plate(52) coupled to the support shaft in such a manner that the airtightness plate is movable in forward and rearward directions, wherein the sealing plate has an outer side edge tightly contacting the inner wall of the nozzle; a handle portion mounted on the support shaft so as to move the sealing plate in forward and rearward directions; a plurality of support legs(55) each of which has an end hinge fixed at the end of the support shaft and the other end tightly contacting the inner wall of the nozzle so as to support the support shaft; and a lever adjustment member mounted on the support shaft so as to open or close the support leg.

Description

Jig for liquid leak test {The apparatus for airtight test of fluid fuel rocket engine}

The present invention relates to a device for checking the leakage state of the supply system connection necessary for the safety of the rocket in the state that the engine is fully assembled to the rocket, in particular installed in the neck of the nozzle of the smallest diameter possible to miniaturization and light weight To a liquid rocket engine leak test fixture.

In general, a rocket is a device that obtains propulsion by exhaling high-pressure gas produced by burning fuel, and such an engine is called a rocket engine. Rocket engines are the most powerful engines of their size, producing 3,000 times more power than engines of the same size. Rockets burn fuel as quickly as they can, consuming a lot of fuel in a short time and generating high temperatures. Therefore, rocket engines need to be very complex and difficult because they have to withstand high temperatures, high pressures and strong forces.

The working principle of a rocket is the law of action-reaction, which allows a powerful rocket to move forward by using reactions of the same magnitude but opposite direction when a force is applied to an object. The combustion of special fuel in the rocket's combustion chamber produces a gas that expands very quickly, the pressure of which is equally effective in all directions within the rocket, and the pressure in one direction is balanced against the pressure in the opposite direction. To achieve. However, the gas flowing behind the rocket is blown out through the nozzle and out of balance with the pressure in front of the rocket, causing the rocket to move forward. The gas exhaled through the nozzle is the 'action' in Newton's law of motion, and the propulsion to push the rocket forward is the opposite.

Therefore, it is very important for the manufacture of the rocket to produce a nozzle which is installed at the end of the rocket to emit gas. By the way, the rocket is to form a large nozzle so as to obtain a large propulsion force, if the size of the nozzle is large, it can not be made as a monolithic body is made by attaching the part by welding or the like method. Therefore, gas leakage may occur at such a connection site, and it is natural to conduct a gas tight test to prevent such gas leakage.

In other words, the most important core component of a liquid rocket is the engine of the launch vehicle, and it is no exaggeration to say that the performance of the engine determines whether the rocket launches successfully. Therefore, it is essential to confirm the safety of the engine, and after the engine is mounted on the rocket, it is required that there is no leakage of fuel and oxidant under a certain pressure.

Conventionally, for the airtight test of the rocket engine, the airtight test was performed after the sealing jig was sealed by using a flange to the nozzle file of the rocket. However, in this method, since the sealing jig is coupled to the largest outlet part of the diameter of the nozzle, the sealing jig becomes very large and the load is excessively acted. As such, when an excessive load is applied to the nozzle, a slight deformation may be caused to the nozzle, thereby causing an abnormality in the performance of the nozzle.

In other words, the conventional airtight test apparatus for a liquid rocket has a problem in that an excessive load is applied because the airtight jig is coupled to the outlet of the nozzle, thereby adversely affecting the performance of the nozzle.

The present invention has been made to solve the above problems of the prior art, it can be installed in the neck portion of the minimum of the diameter of the nozzle can be miniaturized and lightweight, and does not require a separate clamp device using a folding method The purpose is to provide a jig for a rocket engine leak test.

1 is a cross-sectional view showing a state before installing a liquid rocket engine airtight test jig according to the present invention inside the nozzle;

2 is a cross-sectional view showing a state after installing the liquid rocket engine airtight test jig according to the present invention inside the nozzle;

3 is a reference diagram showing the installation form of the support leg seen from the back.

<Explanation of symbols on main parts of the drawings>

51 support shaft 52 sealing plate

53: handle block 54: main handle

55: support leg 55 ': scaffolding

56 leg support block 57 sleeve

58: lever 59: lever adjustment handle

60: O ring 61: stopper

100: nozzle 101: neck (nozzle)

105: coupling part

The present invention for solving the above technical problem and the support shaft is located in the nozzle center portion of the rocket, the sealing plate is coupled to the support shaft to move forward and backward and the outer edge portion is in close contact with the inner wall surface of the nozzle and A plurality of support legs installed on the support shaft to move the sealing plate back and forth, and one end of which is hinged to the end of the support shaft, and the other end is in close contact with the inner wall of the nozzle to support the support shaft. And, the support shaft is characterized in that it comprises a lever adjusting means for expanding or folding the support leg.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the liquid rocket engine airtight test jig according to the present invention supports a support shaft 51 located at a center portion of the nozzle 100 of the rocket and the support shaft 51 can be moved back and forth. A sealing plate 52 coupled to the outer edge portion to be in close contact with the inner wall surface of the nozzle 100, a handle portion installed at the support shaft 51 to move the sealing plate 52 back and forth, and Three support legs 55 hinged to an end of the support shaft 51 and the other end is in close contact with the inner wall surface of the nozzle 100 to support the support shaft 51, and the support shaft 51. It is installed in the) consists of a lever adjustment means for expanding or folding the support leg (55).

The sealing plate 52 is formed to be inclined so that the outer peripheral edge portion is in close contact with the neck portion of the nozzle 100, the outer peripheral edge portion of the sealing plate 52 leaks between the inner wall surface of the nozzle 100 O-ring 60 is installed so that it does not occur. O-ring 60 for airtightness is interposed between the support shaft 51 and the sealing plate 52, and an area in contact with the inner wall of the nozzle 100 of the rocket is enlarged at the lower end of the support lever 55. A scaffold 55 'having a large area is installed.

Here, the sealing plate 52 is preferably made of an aluminum-based material that is a soft material to minimize damage to the inner surface of the nozzle 100, the support leg 55 is made of a steel material to maintain sufficient rigidity Is preferably used.

The handle portion is coupled to the support shaft 51 in the form of a screw and the handle block 53 is in close contact with the plane washer 52 'between the sealing plate 52 and the handle block through rotation The main handle 54 which moves 53 is comprised. The lever adjusting means includes a leg support block 56 movably mounted on the support shaft 51, a sleeve 57 slidably installed on the leg support block 56, and one end of the sleeve 57. A lever 58 hinged and the other end hinged to the support leg 55, a leg adjustment handle 59 installed on the lever support block 56 and moving the sleeve 57 through rotation; It is composed of a stopper 61 coupled to the leg support block 56 by a screw 62 to limit the movement of the sleeve (57).

Liquid rocket engine airtight test jig according to the present invention configured as described above is installed in the nozzle of the rocket engine to seal the inside of the nozzle, it is possible to check whether the leakage occurs in the coupling portion of the nozzle.

The jig of the present invention is installed in the neck 101 portion of the nozzle 100, which is intended to minimize the size of the entire jig by minimizing the diameter of the sealing plate 52. Of course, the sealing plate 52 should be located outside the coupling portion 105 of the nozzle 100, which is a matter of course when considering the nozzle 100.

In order to install the jig of the present invention, the support shaft 51 is aligned with the center line of the nozzle 100, and the lever support block 56 is moved so that the footrest 55 'installed at the end of the leg 55 has a nozzle ( 100) to the inner wall. Thereafter, the leg adjustment handle 59 is operated to move the sleeve 57 so that the footrest 55 'is firmly adhered to the inner wall of the nozzle 100 by the lever 58. Therefore, the support shaft 51 is in the state firmly installed in the center part of the nozzle 100.

In this state, the handle part is operated to bring the sealing plate 52 into close contact with the inner wall of the nozzle 100. That is, by operating the main handle 54 to move the handle block 53, the sealing plate 52 is moved along the support shaft 51 while the inclined edge portion of the sealing plate 52 of the nozzle 100 Make sure that the neck 101 is firmly attached. At this time, since the o-ring 60 is interposed between the sealing plate 52 and the inner wall of the nozzle 100, and the o-ring 60 is also interposed between the sealing plate 52 and the support shaft 51. Inside and outside of the sealing plate 52 is completely blocked.

Thereafter, the nozzle 100 is attached to the rocket engine and the airtight test is performed. In the airtight test, it is checked whether gas leakage occurs at the coupling part 105 of the nozzle 100.

The liquid rocket engine airtight test jig according to the present invention configured as described above has a simple structure and is installed on the neck of the nozzle, so that the sealing plate is compact and easily detachable, and thus there is an advantage that the airtight test can be easily performed.

Claims (8)

A support shaft positioned at the center portion of the nozzle of the rocket, a sealing plate coupled to the support shaft so as to be movable forward and backward, and an outer edge thereof closely attached to the inner wall surface of the nozzle, and installed at the support shaft to fix the sealing plate. A plurality of support legs which are moved forward and backward, one end of which is hinged to the end of the support shaft and the other end is in close contact with the inner wall surface of the nozzle to support the support shaft, and is installed on the support shaft to support the leg Liquid rocket engine airtight test jig comprising a lever adjustment means for extending or folding. The method of claim 1, The sealing plate jig for liquid rocket engine airtight test, characterized in that the outer peripheral edge portion is formed inclined so as to be in close contact with the neck portion of the nozzle. The method of claim 1, Liquid rocket engine airtight test jig characterized in that the O-ring is installed on the outer peripheral edge portion of the sealing plate so that leakage does not occur between the inner wall surface of the nozzle. The method of claim 1, The handle portion is coupled to the support shaft in the form of a screw and the handle block which is in close contact with the plane washer between the sealing plate and a liquid comprising a main handle for moving the handle block through rotation Rocket engine leak test fixture. The method of claim 1, The lever adjusting means includes a leg support block movably installed on the support shaft, a sleeve slidably installed on the leg support block, a leg adjustment handle installed on the lever support block and moving the sleeve through rotation; Liquid rocket engine airtight test jig characterized in that the one end is hinged to the sleeve and the other end is composed of a lever hinged to the support leg. The method of claim 5, The lever adjusting means is a liquid rocket engine airtight test jig characterized in that the stopper is coupled to the leg support block by screw to limit the movement of the sleeve. The method of claim 1, Liquid rocket engine airtight test jig, characterized in that the O-ring for sealing between the support shaft and the sealing plate is interposed. The method of claim 1, The support leg is a liquid rocket engine airtight test jig characterized in that it has a scaffold having a large area at its lower end so that the area in contact with the inner wall of the rocket nozzle is enlarged.