KR102480591B1 - Shear coaxial injector of rocket engine - Google Patents

Abstract

The present invention relates to a coaxial front-end injector of a rocket engine, and more particularly, an oxidant inlet to which a liquid oxidizer is supplied, and an oxidant outlet formed integrally at the lower end of the oxidant inlet and having a plurality of expansion passages protruding outward at regular intervals along the edge. An oxidizing agent injector comprising a part; A fuel inlet enclosing the oxidizer inlet and supplying gaseous fuel, and a fuel outlet formed integrally at the lower end of the fuel inlet to surround the oxidant outlet and protruding inward along an edge between the fuel outlet inserted between the expansion passages. It consists of a fuel injector; there is an effect that can further expand the area where atomization and mixing occur by increasing the surface area in which the liquid oxidant and the gaseous fuel are in contact.

Description

Shear coaxial injector of rocket engine

The present invention relates to a coaxial front injector for a rocket engine, and more particularly, to a coaxial front injector for a rocket engine capable of improving the atomization and mixing efficiency of a liquid oxidant used as a propellant and a gaseous fuel.

In a liquid propellant rocket engine, thrust is obtained by compressing and expanding combustion gas generated by injecting/mixing propellants through a mixer and then burning them in a combustion chamber. enough to do

Accordingly, a large number of injectors (injectors) are densely arranged and used at the top of the combustion chamber for injection/mixing of the propellant. The propellants injected through the large number of injectors installed in this way collide with each other and are injected into very small droplets. These atomized propellants can be well mixed with each other to obtain strong thrust.

Therefore, an appropriately shaped injector is required to improve the atomization and mixing effect of the injected propellant.

Registered Patent No. 10-2166170

The present invention has been made to solve the above problems of the prior art, to provide a coaxial front-end injector of a rocket engine capable of improving the atomization and mixing efficiency of the oxidant and the fuel by increasing the surface area where the liquid oxidant and gaseous fuel meet. It has a purpose.

The coaxial front-end injector of a rocket engine according to the present invention for solving the above problems is formed integrally with an oxidizing agent inlet to which a liquid oxidizing agent is supplied and a lower end of the oxidizing agent inlet, and a plurality of expansion passages along the edge are directed outward at regular intervals. an oxidizing agent injector including a protruding oxidizing agent outlet; A fuel inlet enclosing the oxidizer inlet and supplying gaseous fuel, and a fuel outlet formed integrally at the lower end of the fuel inlet to surround the oxidant outlet and protruding inward along an edge between the fuel outlet inserted between the expansion passages. It consists of; fuel injector.

Here, the protruding length of the expansion passage of the oxidizing agent outflow part gradually increases downward, so that the cross-sectional area of the passage through which the oxidizing agent flows out gradually widens, and the convex part of the fuel outflow part gradually becomes thicker toward the bottom, so that the fuel flows out. The cross-sectional area of the passage gradually narrows.

Further, a distribution groove is formed at a lower end of the expansion passage of the oxidizing agent outlet.

In addition, the lower end of the oxidizing agent outlet is located a predetermined distance above the lower end of the fuel outlet.

In addition, a plurality of auxiliary passages protrude outward along an edge of the expansion passage of the oxidizing agent outlet, and protrusions inserted between the auxiliary passages protrude inward between convex portions of the fuel outlet.

In the coaxial front-end injector of the rocket engine of the present invention configured as described above, the expansion passage is formed at the oxidant outlet and the convex portion inserted into the expansion passage is formed at the fuel outlet, so that the liquid oxidant and the gaseous fuel come into contact. There is an advantage in that the area where atomization and mixing occur can be further expanded by increasing the surface area.

In addition, since the expansion passage expands toward the bottom and the outflow cross-sectional area of the oxidizing agent widens, and the convex part becomes thicker toward the bottom and the outflowing cross-sectional area of the fuel decreases, a speed difference occurs between the flow rate of the oxidizing agent and the flow rate of the fuel, resulting in collision between the oxidizing agent and the fuel. It has the advantage of promoting atomization and mixing by inducing.

In addition, the oxidizing agent can flow into the space between the oxidizing agent outlet and the fuel outlet through the distribution groove, and the fuel can flow into the oxidizing agent outlet, so that the oxidizing agent and the fuel collide directly to atomize and mix the oxidizing agent and the fuel. has the advantage of further promoting

In addition, since an empty space is formed between the oxidizing agent outlet and the fuel outlet, and the oxidizing agent and the fuel are preliminarily mixed in this space, there is an advantage in that the oxidizing agent and the fuel are mixed more finely.

1 and 2 show a coaxial front injector of a rocket engine according to the present invention.
3 and 4 are front cross-sections of a coaxial front-end injector of a rocket engine according to the present invention;
5 is a side cross-sectional view of a coaxial front-end injector of a rocket engine according to the present invention;

Hereinafter, an embodiment of a coaxial front-end injector of a rocket engine according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are views showing a coaxial front injector of a rocket engine according to the present invention, FIGS. 3 and 4 are views showing a front section of the coaxial front injector of a rocket engine according to the present invention, and FIG. It is a diagram showing a side cross-section of a coaxial front-end injector of a rocket engine by .

A coaxial front-end injector of a rocket engine according to the present invention is composed of an oxidant injector 10 and a fuel injector 20 surrounding the oxidant injector 10 at a predetermined distance apart.

The oxidizing agent injector 10 is composed of an oxidizing agent inlet 11 and an oxidizing agent outlet 12 integrally formed at a lower end of the oxidizing agent inlet 11 .

The oxidizing agent inlet 11 is formed in a cylindrical shape having the same diameter and thickness, and an oxidizing agent in a liquid state is supplied through an open upper surface.

The oxidizing agent outlet 12 is integrally connected to the open lower end of the oxidizing agent inlet 11, and a plurality of expansion passages 12a are formed to protrude outward at regular intervals.

Since the expansion passage 12a protrudes outward along the edge of the oxidizing agent outlet 12 at regular intervals, the overall shape of the oxidizing agent outlet 12 when viewed from the bottom is a plurality of petals arranged radially. shaped like a flower.

The outward protruding length L2 of the expansion passage 12a gradually increases toward the lower side. Accordingly, the cross-sectional area of the flow path of the oxidizing agent outlet 12 through which the oxidizing agent flows out becomes wider toward the lower side.

Since the cross-sectional area of the passage through which the oxidizing agent flows in the oxidizing agent outlet 12 gradually widens, the flow rate of the oxidizing agent introduced into the oxidizing agent outlet 12 decreases toward the lower end.

A distribution groove 12c is formed at the lower end of the expansion passage 12a of the oxidizing agent outlet 12.

The distribution groove 12c is a passage through which the liquid oxidant flowing inside the oxidant injector 10 and the gaseous fuel flowing between the oxidant injector 10 and the fuel injector 20 cross each other so that mixing is achieved. play a role

The distribution groove 12c is formed at the end of the expansion passage 12a, but is also formed on the concave surface 12b of the oxidizing agent outlet 12 interposed between the expansion passages 12a to further promote mixing of the oxidant and fuel. can make it

Meanwhile, the concave surface 12b interposed between the expansion passages 12a of the oxidizing agent outlet 12 is inclined toward the center of the oxidizing agent outlet 12 toward the lower end of the oxidizing agent outlet 12. . In other words, the length L1 in which the concave surface 12b of the oxidizing agent outlet 12 is recessed inward is shorter than the length L2 in which the expansion passage 12a protrudes outward.

The fuel injector 20 is composed of a fuel inlet 21 and a fuel outlet 22 integrally formed at a lower end of the fuel inlet 21 .

The fuel inlet 21 is formed in a cylindrical shape having the same diameter and thickness and surrounds the oxidizer inlet 11 . Gaseous fuel is supplied to the fuel inlet 21, and the fuel flows through a space between the oxidizer injector 10 and the fuel injector 20.

The fuel outlet 22 is formed integrally connected to the open lower end of the fuel inlet 21 and surrounds the oxidant outlet 12, wherein a plurality of convex portions 22a protrude inward at regular intervals. is formed

Since the convex portions 22a protrude inward along the edge of the fuel outlet 22 at regular intervals, when the fuel outlet 22 is viewed from the bottom, a plurality of petals are radially arranged like a flower. form

The convex portion 22a is inserted between the expansion passages 12a of the oxidizing agent outlet 12, and the thickness gradually increases toward the lower side, so that the cross-sectional area of the passage through which the fuel is discharged gradually narrows toward the lower side. That is, the distance between the oxidizing agent outlet 12 and the fuel outlet 22 gradually narrows toward the bottom due to the convex portion 22a gradually becoming thicker toward the lower end. Therefore, the flow rate of the fuel introduced between the oxidizing agent outlet 12 and the fuel outlet 22 increases toward the lower end.

As described above, the speed of the oxidizing agent flowing inside the oxidizing agent outlet 12 decreases toward the lower end, and the speed of the fuel flowing in the space between the oxidizing agent outlet 12 and the fuel outlet 22 toward the lower end. Since the speed is faster, the difference in velocity between the oxidizer and the fuel is greater and the collision between the oxidizer and the fuel is more promoted, resulting in smaller propellant particles and better mixing.

Meanwhile, when the oxidizer injector 10 is installed to be surrounded by the fuel injector 20, the lower end of the oxidant outlet 12 is located a certain distance above the lower end of the fuel outlet 22.

Since a certain space is formed between the lower end of the fuel outlet 22 and the lower end of the oxidant outlet 12, the oxidizer and the fuel are first (or preliminary) mixed in this space, and then the fuel outlet 22 sprayed out

In addition, a plurality of auxiliary passages 12d may protrude outward along the edge of the expansion passage 12a of the oxidizing agent outlet 12, and the auxiliary passage 12d is between the convex portions 22a of the fuel outlet 22. ) The protrusion 22b inserted between may protrude inward.

The auxiliary passage 12d plays the same role as the expansion passage 12a with respect to the oxidizing agent outlet 12 with respect to the expansion passage 12a. That is, the auxiliary passage 12d is formed in the expansion passage 12a to increase the cross-sectional area of the passage through which the oxidizing agent flows, thereby reducing the flow rate of the oxidizing agent.

The protrusion 22b can be repeatedly formed in smaller and smaller sizes so that the cross section of the fuel injector 20 has a shape such as a fractal structure, and the protrusion 22b is formed at the outlet of the injector with fuel. By increasing the contact area of the oxidizing agent, atomization of the liquid oxidizing agent is promoted.

And, since the distribution of the injection speed difference between the liquid oxidizing agent and the gaseous fuel is not constant along the circumference of the injector due to the protrusion 22b, the non-uniformity of the generated shear force accelerates the atomization of the propellant.

10: oxidizing agent injector 11: oxidizing agent inlet
12: oxidizing agent outlet 12a: expansion passage
12b: concave surface 12c: distribution groove
12d: auxiliary oil 20: fuel injector
21: fuel inlet 22: fuel outlet
22a: convex portion 22b: projection

Claims (5)

An oxidizing agent inlet 11 through which liquid oxidizing agent is supplied, and an oxidizing agent outlet 12 integrally formed at the lower end of the oxidizing agent inlet 11 and protruding outward at regular intervals with a plurality of expansion passages 12a along the edge An oxidizing agent injector 10 comprising a;
The fuel inlet 21 that surrounds the oxidizer inlet 11 and supplies gaseous fuel, and is integrally formed at the lower end of the fuel inlet 21 to surround the oxidizer outlet 12 and protrude inward along the edge. A fuel injector 20 including a fuel outlet 22 in which the convex portion 22a is inserted between the expansion passages 12a;
A plurality of auxiliary passages 12d protrude outward along the edge of the expansion passage 12a of the oxidizing agent outlet 12,
A coaxial front-end injector of a rocket engine, characterized in that a protrusion (22b) inserted between the auxiliary passages (12d) protrudes inward between the convex portions (22a) of the fuel outlet (22).
The method of claim 1,
The protruding length of the expansion passage 12a of the oxidizing agent outlet 12 gradually increases downward, so that the cross-sectional area of the passage through which the oxidizing agent flows out gradually widens.
The convex portion (22a) of the fuel outlet (22) is gradually thicker toward the lower side, so that the cross-sectional area of the passage through which the fuel is discharged gradually narrows.
The method of claim 1,
A coaxial front-end injector of a rocket engine, characterized in that a distribution groove (12c) is formed at the lower end of the expansion passage (12a) of the oxidizing agent outlet (12).
The method of claim 1,
The oxidizer outlet 12 is a coaxial front-end injector of a rocket engine, characterized in that the lower end is located a certain distance above the lower end of the fuel outlet 22.
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