KR101876755B1 - Seal testing apparatus for liquid rocket engine and thrust chamber - Google Patents

Abstract

It is a technical object of the present invention to provide a liquid rocket engine and a gas tightness testing device for a combustor which can maintain the airtightness of a combustor and an engine even when a heat shielding coating is applied to a combustion chamber and a nozzle neck of a liquid rocket combustor. To this end, the liquid rocket engine and airtightness testing device for a combustor of the present invention includes a first portion that is a heat shield coating, including a combustion chamber and a nozzle neck, and a second portion that is not thermally shielded coating below the nozzle neck And an airtightness testing apparatus for a liquid rocket engine and a combustor used in a liquid rocket engine equipped with the same, the upper plate being provided over the nozzle neck of the first portion; A lower plate provided in the second portion; A load supporting portion for supporting a load of the lower plate on the upper plate; And an annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the inner surface of the second portion.

Description

[0001] Seal testing apparatus for liquid rocket engines and combustors [0002]

The present invention relates to an airtightness testing apparatus for a liquid rocket engine and a combustor.

Generally, a liquid rocket engine is an engine that reacts with propellant at a high speed to convert heat energy generated by combustion into kinetic energy to obtain a reaction. Since the oxidant is supplied together with the fuel, even when oxygen is not supplied from the outside It is used mainly in space, such as propulsion of spacecraft or missiles.

On the other hand, if the liquid rocket engine is manufactured, the combustion test is carried out on the test equipment to verify its performance before it is fired. In particular, prior to the combustion test, a test is conducted to confirm the airtightness of the liquid rocket engine and combustor. In other words, ensure that the liquid rocket engine, combustor, various propellant supply lines, and various sensor connections are kept confidential. This is because, if the airtightness is not maintained, a hot gas or a propellant may leak, resulting in explosion or thermal damage of the liquid rocket engine, the combustor, and the like.

1 is a schematic view of a conventional airtightness testing device for a liquid rocket engine and a combustor.

1, a conventional test apparatus 10 for a liquid rocket engine and a combustor is provided with a nozzle neck portion 1c provided between the combustion chamber 1a and the nozzle 1b, An annular rubber member 12 which surrounds the outer surface of the plate 11 and prevents damage to the thermally conductive material coated on the inner surface of the nozzle neck 1c, And an O-ring 13 for sealing between the outer surface of the plate 11 and the inner surface of the nozzle neck portion 1c. Therefore, the nozzle neck portion 1c can be completely sealed by the O-ring 13 and the like, and the liquid rocket engine (not shown), the combustor 1, the various propellant supply lines ) And various sensor connections (not shown) can be tested to confirm that the airtightness is maintained.

However, the conventional airtightness testing apparatus 10 for a liquid rocket engine and a combustor has a limit that can not be used when the inner surface of the nozzle neck portion 1c of the combustor 1 is made of thermal barrier coating .

That is, the combustion chamber 1a of the combustor 1 of the liquid rocket engine receives a very high thermal load because a high temperature combustion gas of about 3500 K is generated and flows. A heat shielding coating (not shown) is applied to the inner surfaces of the combustion chamber 1a and the nozzle neck portion 1c to prevent heat damage to the combustion chamber 1a and the nozzle neck portion 1c from such a high thermal load and to reduce thermal load . The heat shielding coating consists of two layers. The first layer lying on the inner side has a metal-based bond coat and the second layer on the outer side facing the hot combustion gas is applied with a ceramic coating in a plasma spraying manner. In particular, the second layer is comprised of a ceramic coating, the surface of which is rough, and there are many pores. Therefore, the airtightness of the conventional rocket engine and the o-ring 13 of the airtightness testing apparatus 10 for a combustor can not be maintained due to a large number of pores.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a liquid rocket engine and a gas tightness testing apparatus for a combustor that can maintain the airtightness of a combustor and a liquid rocket engine even when a heat shield coating is applied to the combustion chamber and the nozzle neck.

In order to achieve the above object, the present invention provides a hermeticity testing apparatus for a liquid rocket engine and a combustor, comprising: a first portion having a heat shielding coating including a combustion chamber and a nozzle neck; And an upper plate provided over the nozzle portion of the first portion, the upper plate being disposed on the nozzle portion of the first portion; A lower plate provided in the second portion; A load supporting portion for supporting a load of the lower plate on the upper plate; And an annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the inner surface of the second portion.

The airtightness testing apparatus for a liquid rocket engine and a combustor according to an embodiment of the present invention may include an airtightness testing device for surrounding an outer surface of the outer surface of the lower plate and preventing an inner surface of the second portion from being damaged by the lower plate, The lower damage preventing member may be provided.

The sealing member may be placed on the upper side of the outer surface of the lower plate, and the lower damage preventing member may be placed under the sealing member.

The outer surface of the lower plate may have a step for seating the sealing member or the lower damage preventing member.

Wherein the sealing member includes: an outer side close contact portion which is in close contact with an outer side surface of the lower plate; An inner side close contact portion which is in close contact with an inner side surface of the second portion; And a lower connection portion connecting the lower end of the outer side close contact portion and the lower end of the inner side close contact portion so that the outer side close contact portion and the inner side close contact portion are opened upward.

The upper end of the lower damage preventing member may be caught in the step, and the lower connecting portion may be seated in the upper end of the lower damage preventing member.

The airtightness testing device for a liquid rocket engine and a combustor according to an embodiment of the present invention may include an annular upper damage prevention member which surrounds the outer surface of the upper plate and prevents the heat shielding coating from being damaged by the upper plate .

The upper plate may have a first hollow space in the form of a groove or a through hole, and a second hollow space in the form of a groove may be provided in the lower plate.

Wherein the load supporting portion includes: a fastening hole formed at the center of the upper plate; A through hole formed at the center of the lower plate; A support rod whose one end is fastened to the fastening hole and the other end passes through the through hole; And a fastening nut fastened to the other end of the support rod.

The fastening nut may have a closed bottom structure, and an upper end surface thereof may be in contact with the lower plate.

The load supporting portion may further include an O-ring, which is provided on the upper surface of the coupling nut and seals between the coupling nut and the lower plate.

Each of the upper plate and the lower plate may further include a jig fixing groove for fixing the outer assembly jig.

As described above, the airtightness testing apparatus for the liquid rocket engine and the combustor according to the embodiment of the present invention can have the following effects.

According to an embodiment of the present invention, there is provided a technical construction including an upper plate, a lower plate, a load supporting portion, and a sealing member, so that the lower plate is supported by a load supporting portion on an upper plate spanning the nozzle neck, It is possible to seal between the lower plate and the inner surface of the second part by the sealing member and to keep the airtightness with the combustor even when the heat shield coating is applied to the combustion chamber and the nozzle neck. And can ultimately be tested to ensure that the various propellant feed lines and various sensor connections that are assembled to the liquid rocket engine and combustor through the pressure applied to the combustion chamber are kept airtight.

1 is a schematic view of a conventional airtightness testing device for a liquid rocket engine and a combustor.
FIG. 2 is a schematic view of a gas tightness testing apparatus for a liquid rocket engine and a combustor according to an embodiment of the present invention.
3 is an enlarged view showing the "A" portion of the airtightness testing apparatus for the liquid rocket engine and the combustor of FIG.
Fig. 4 is an enlarged view showing the "B" part of the airtightness testing apparatus for the liquid rocket engine and the combustor of Fig. 2;

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

FIG. 2 is a schematic view of an airtightness testing apparatus for a liquid rocket engine and a combustor according to an embodiment of the present invention, and FIG. 3 is an enlarged view of an airtightness testing apparatus for a liquid rocket engine and a combustor of FIG. And Fig. 4 is an enlarged view showing the "B" portion of the airtightness testing apparatus for the liquid rocket engine and the combustor of Fig.

2 to 4, a liquid-tight testing apparatus 100 for a liquid rocket engine and a combustor according to an embodiment of the present invention includes a combustion chamber 1a and a nozzle neck portion 1c, (1) containing a first portion (P1) of the nozzle neck portion (1c) and a second portion (P2) not covered with a heat shielding coating below the nozzle neck portion (1c) and a liquid A lower plate 120, a load supporting portion 130, and a sealing member 140. The upper plate 110, the lower plate 120, the load supporting portion 130, Hereinafter, each of the constituent elements will be described in detail with continued reference to Figs. 2 to 4. Fig.

The upper plate 110 is a component that supports the load of the lower plate 120 together with the load supporting portion 130 and has a first portion P1 of the combustor 1, (Not shown). Therefore, when the pressure is applied to the combustion chamber 1a for the airtightness test, the upper plate 110 can be pressed downward and more firmly fixed to the nozzle neck portion 1c in the form of a wedge.

Further, as shown in FIG. 2, the upper plate 110 may have a first hollow space H1 in the form of a groove or a through-hole. Therefore, the weight of the upper plate 110 can be reduced through the first hollow space H1 to facilitate assembly.

As shown in FIG. 2, the upper plate 110 may further include a jig fixing groove T for fixing a jig for external assembly (not shown). Therefore, when the external assembly jig can be fixed through the jig fixing groove T and the operator can not directly assemble the upper plate 110 into the combustor due to the small size of the combustor 1, The assembly jig can be fixed to the jig fixing groove T so that the upper plate 110 can be easily assembled.

The lower plate 120 is a component for providing the airtightness of the combustor 1 together with the sealing member 140 and is not a heat shielding coating in the combustor 1 as shown in FIGS. And is provided in the second portion P2 having no pores. Therefore, the lower plate 120 can be provided in the second portion P2 having no pore and not the first portion P1 having a large number of pores on its inner surface due to the heat shielding coating, The outer surface and the inner surface of the second portion P2 of the combustor 1 can be sealed by the sealing member 140. [

4, a step 125 for seating the sealing member 140 and the lower damage preventing member 150 may be formed on the outer surface of the lower plate 120. [ Therefore, even if the sealing member 140 is pressed downward by applying pressure to the combustion chamber 1a during the airtightness test, the sealing member 140 may be caught by the step 125 and its movement may be stopped. Ultimately, due to the pressure applied while the sealing member 140 is stopped, the space between the outer side close contact portion 141 and the inner side close contact portion 142 of the sealing member 140, which will be described later, The tight contact portion 141 is further brought into close contact with the outer surface of the lower plate 120 and the inner side close contact portion 142 can be further brought into close contact with the inner surface of the second portion P2 of the combustor 1, It is possible to firmly maintain the airtightness between the first portion 120 of the combustor 1 and the second portion P2 of the combustor 1. [

As shown in FIGS. 2 and 4, the lower plate 120 may have a groove-shaped second hollow space H2. Therefore, the weight of the upper plate 110 can be reduced through the second hollow space H2. In particular, since the lower plate 120 is a component that must provide airtightness together with the sealing member 140, the second hollow space H2 can not have a through-hole shape unlike the upper plate 110 described above.

As shown in FIG. 2, the lower plate 120 may further include a jig fixing groove T for fixing a jig for external assembly (not shown). Therefore, when the external assembly jig can be fixed through the jig fixing groove T and the operator can not directly assemble the lower plate 120 into the combustor 1 due to the small size of the combustor 1, The external assembly jig in the form of a rod is fixed to the jig fixing groove T so that the lower plate 120 can be easily assembled.

The load supporting portion 130 is a component for supporting the load of the lower plate 120 together with the upper plate 110. The load supporting portion 130 may be formed by connecting the upper plate 110 and the lower plate 120, .

For example, the load supporting portion 130 may include a fastening hole 131, a through hole 132, a support rod 133, and a fastening nut 134, as shown in FIG. The fastening hole 131 may be formed at the center of the upper plate 110 and the through hole 132 may be formed at the center of the lower plate 120 and the support rod 133 may be formed in the fastening hole 131 The other end can pass through the through hole 132 and the coupling nut 134 can be fastened to the other end of the support rod 133. [

2, the fastening nut 134 may have a closed structure at its lower end, and the upper end surface thereof may be in contact with the lower plate 120. As shown in FIG. Therefore, a tight airtightness can be maintained through the closed structure of the lower end of the coupling nut 134. [

2, an O-ring (not shown) is provided on the upper surface of the lock nut 134 and seals between the lock nut 134 and the lower plate 120 135). Therefore, through this O-ring 135, more firmly airtightness can be maintained between the upper end surface of the lock nut 134 and the opposite surface of the lower plate 120.

The sealing member 140 is a component for providing airtightness of the combustor 1 together with the lower plate 120 and has an annular shape as shown in Figs. One side of the outer surface can be covered.

For example, the sealing member 140 may include an outer side close contact portion 141, an inner side close contact portion 142, and a lower connection portion 143, as shown in FIG. The outer side close contact portion 141 is a portion that is in close contact with the outer surface of the lower plate 120 and the inner side close contact portion 142 is a portion that is in close contact with the inner surface of the second portion P2 of the combustor 1 And the lower connection part 143 are formed so as to be opened upward between the outer side close contact part 141 and the inner side side close contact part 142 so that the lower end of the outer side close contact part 141 and the inner side side close contact part 142 ) To the lower end of the frame. Therefore, the space between the outer side close contact portion 141 and the inner side close contact portion 142, which is opened upward by the pressure applied while the sealing member 140 is stopped by the step 125, The outer side close contact portion 141 is more closely attached to the outer surface of the lower plate 120 and the inner side close contact portion 142 is more closely attached to the inner surface of the second portion P2 of the combustor 1 And can firmly maintain airtightness between the lower plate 120 and the second portion P2 of the combustor 1. [

In addition, the airtightness testing apparatus 100 for a liquid rocket engine and a combustor according to an embodiment of the present invention may further include a lower damage preventing member 150, as shown in FIGS. 2 and 4 . The lower damage preventing member 150 has an annular shape and surrounds the other portion of the outer surface of the lower plate 120 by the portion of the sealing member 140 wound around the lower plate 120, To prevent damage to the inner surface of the second portion P2. For example, the lower damage preventing member 150 may be made of a material such as rubber.

4, the sealing member 140 can be placed on the upper side of the outer surface of the lower plate 120, and the lower damage preventing member 150 can be placed under the sealing member 140 . Therefore, sufficient pressure is transmitted to the space between the outer side close contact portion 141 and the inner side close contact portion 142 of the upper opening type sealing member 140 so that the outer side close contact portion 141 and the inner side close contact portion 142 (142) can be sufficiently opened.

4, the upper end portion of the lower damage preventing member 150 may be caught in the step 125, and the lower connecting portion 143 may be seated in the upper end portion of the lower damage preventing member 150 . Therefore, the upper end portion of the lower damage preventing member 150 can be more strongly fixed by the sealing member 140 to be pressed.

In addition, as shown in FIG. 3, the airtightness testing apparatus 100 for a liquid rocket engine and a combustor according to an embodiment of the present invention has an annular shape and surrounds the outer surface of the upper plate 110 And an upper damage preventing member 160 that prevents the heat shielding coating from being damaged by the upper plate 110. [ For example, the upper damage preventing member 160 may be made of a material such as rubber.

Hereinafter, the process of assembling the airtightness testing apparatus 100 for the liquid rocket engine and the combustor according to the embodiment of the present invention to the combustor 1 will be described with reference to FIGS. 2 to 4. FIG.

First, an upper damage preventing member 160 is assembled to the outer surface of the upper plate 110 and the upper damage preventing member 160 is attached to the nozzle neck 1c of the combustor 1 in the same manner as the insertion of the conventional plate 11 (110) into the combustor (1). Unlike the conventional plate 11 of FIG. 1, the upper plate 110 serves to fix the lower plate 120 by a pressure load applied during the airtightness test of the combustor 1. Further, when the combustor 1 is small enough that a person can not work, the jig fixing groove (not shown) is fixed to the jig fixing groove T to assemble the upper plate 110.

Then, the support rod 133 of the load supporting member 130 is assembled to the upper plate 110. The support rod 133 is connected to the lower plate 120 to support a load received from the lower plate 120 during an airtight test.

Thereafter, in the first portion P1 where the heat shielding coating exists, the lower plate 120 assembled to the second portion P2 without pores is prepared because the airtightness can not be maintained due to the pores. And the lower damage preventing member 150 is assembled to the outer surface of the lower plate 120. Further, a substantially "C" shaped sealing member 140 for holding the airtightness is assembled to the outer surface of the lower plate 120. In particular, in the case of the conventional O-ring (13 in FIG. 1), if there is a gap between the O-ring and the inner surface of the combustor, the airtightness can not be maintained. In the case of the sealing member 140 of the present invention, 120 and the inner surface of the combustor 1 is increased, the airtightness between the inner and outer surfaces of the combustor 1 can be maintained.

Then, the lower plate 120 is assembled to the support rod 133. Further, when the combustor 1 is small enough that a person can not work, the jig fixing jig (not shown) is fixed to the jig fixing groove T to assemble the lower plate 120 to the support rod 133. Particularly, the lower plate 120 is assembled to the support rod 133 using the fastening nut 134. The coupling nut 134 has a closed bottom structure and an O-ring 135 is provided on the upper end surface of the coupling nut 134 in contact with the lower plate 120.

When the assembly is completed, pressurization is applied to the inside of the combustor 1 to perform the airtightness test of the liquid rocket engine (not shown) and the combustor 1.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: Combustor 1a: Combustion chamber
1b: nozzle 1c: nozzle neck
P1: the first part with the heat shielding coating
P2: the second portion not coated with a heat shield
100: Airtight test equipment for liquid rocket engines and combustors
110: upper plate 120: lower plate
125: step 130: load supporting part
131: fastening hole 132: through hole
133: support rod 134: fastening nut
135: O-ring 140: Sealing member
141: outer side close contact portion 142: inner side close contact portion
143: Lower connection part 150: Lower damage prevention part
151: upper end portion of the lower damage preventing member
160: upper damage preventing member H1: first empty space part
H2: second empty space part T: jig fixing groove

Claims (12)

delete delete A combustor including a first portion having a heat shielding coating including a combustion chamber and a nozzle neck portion and a second portion not subjected to a heat shield coating below the nozzle neck, and a liquid rocket engine and a combustion With the airtightness testing device,
An upper plate disposed over the nozzle neck of the first portion;
A lower plate provided in the second portion;
A load supporting portion for supporting a load of the lower plate on the upper plate; And
An annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the second portion;
Lt; / RTI >
The airtightness testing device for the liquid rocket engine and the combustor,
A lower damaging preventing member which surrounds another portion of the outer surface of the lower plate and prevents the inner surface of the second portion from being damaged by the lower plate,
Further comprising:
The sealing member is placed on the upper side of the outer surface of the lower plate,
The lower damage preventing member may be disposed below the sealing member
Airtightness testing equipment for liquid rocket engines and combustors. 4. The method of claim 3,
The outer surface of the lower plate is formed with a step for seating the sealing member or the lower damage preventing member
Airtightness testing equipment for liquid rocket engines and combustors. 5. The method of claim 4,
The sealing member
An outer side close contact portion which is in close contact with an outer side surface of the lower plate;
An inner side close contact portion which is in close contact with an inner side surface of the second portion; And
And a lower connection portion connecting the lower end of the outer side close contact portion and the lower end of the inner side side close contact portion so as to have an open top between the outer side close contact portion and the inner side close contact portion,
Containing
Airtightness testing equipment for liquid rocket engines and combustors. The method of claim 5,
The upper end of the lower damage preventing member is caught by the step,
The lower connection portion is seated on the upper end portion of the lower damage preventing member
Airtightness testing equipment for liquid rocket engines and combustors. A combustor including a first portion having a heat shielding coating including a combustion chamber and a nozzle neck portion and a second portion not subjected to a heat shield coating below the nozzle neck, and a liquid rocket engine and a combustion With the airtightness testing device,
An upper plate disposed over the nozzle neck of the first portion;
A lower plate provided in the second portion;
A load supporting portion for supporting a load of the lower plate on the upper plate; And
An annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the second portion;
Lt; / RTI >
The airtightness testing device for the liquid rocket engine and the combustor,
An upper damage-preventing member, which covers the outer surface of the upper plate and prevents the heat-shielding coating from being damaged by the upper plate,
Further comprising
Airtightness testing equipment for liquid rocket engines and combustors. A combustor including a first portion having a heat shielding coating including a combustion chamber and a nozzle neck portion and a second portion not subjected to a heat shield coating below the nozzle neck, and a liquid rocket engine and a combustion With the airtightness testing device,
An upper plate disposed over the nozzle neck of the first portion;
A lower plate provided in the second portion;
A load supporting portion for supporting a load of the lower plate on the upper plate; And
An annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the second portion;
Lt; / RTI >
Wherein the upper plate is provided with a first hollow space in the form of a groove or a through-hole,
The lower plate is provided with a groove-shaped second hollow space
Airtightness testing equipment for liquid rocket engines and combustors. A combustor including a first portion having a heat shielding coating including a combustion chamber and a nozzle neck portion and a second portion not subjected to a heat shield coating below the nozzle neck, and a liquid rocket engine and a combustion With the airtightness testing device,
An upper plate disposed over the nozzle neck of the first portion;
A lower plate provided in the second portion;
A load supporting portion for supporting a load of the lower plate on the upper plate; And
An annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the second portion;
Lt; / RTI >
The load-
A fastening hole formed at the center of the upper plate;
A through hole formed at the center of the lower plate;
A support rod whose one end is fastened to the fastening hole and the other end passes through the through hole; And
And a fastening nut fastened to the other end of the support rod
Containing
Airtightness testing equipment for liquid rocket engines and combustors. The method of claim 9,
The fastening nut
The lower end of which has a closed structure,
The upper face of which is in contact with the lower plate
Airtightness testing equipment for liquid rocket engines and combustors. 11. The method of claim 10,
The load-
And an O-ring provided on the upper end surface of the coupling nut for sealing between the coupling nut and the lower plate,
Further comprising
Airtightness testing equipment for liquid rocket engines and combustors. A combustor including a first portion having a heat shielding coating including a combustion chamber and a nozzle neck portion and a second portion not subjected to a heat shield coating below the nozzle neck, and a liquid rocket engine and a combustion With the airtightness testing device,
An upper plate disposed over the nozzle neck of the first portion;
A lower plate provided in the second portion;
A load supporting portion for supporting a load of the lower plate on the upper plate; And
An annular sealing member surrounding a portion of the outer surface of the lower plate and sealing between the inner surface of the lower plate and the second portion;
Lt; / RTI >
The upper plate and the lower plate are each provided with a jig fixing groove for fixing the outer assembly jig
Airtightness testing equipment for liquid rocket engines and combustors.

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