KR102473357B1 - Turbo Pump With Anti-Rotating Floating Ring Seal - Google Patents

Abstract

The present invention relates to a turbo pump that suppresses over-rotation of the floating ring and prevents pressure fluctuation through deformation of the shape of the floating ring and the inner casing provided in the secondary passage used for cooling the bearing, the turbo pump according to the present invention includes a floating ring and an inner casing, and the floating ring and the inner casing may include a latch or resistor that generates resistance while minimizing wear due to friction.

Description

A turbo pump including a floating ring seal for inhibiting rotation {Turbo Pump With Anti-Rotating Floating Ring Seal}

The present invention relates to a floating ring installed in a flow path provided for reasons such as cooling a bearing inside a turbo pump and adjusting axial thrust, and more particularly, a floating ring that prevents pressure fluctuation while suppressing rotation by an impeller by itself through a shape. It relates to a turbopump comprising a ring seal.

In general, a liquid propellant rocket generates thrust by injecting high-temperature, high-pressure gas by burning a liquid oxidant such as liquid oxygen in a cryogenic state and fuel such as kerosene and liquid hydrogen. At this time, the oxidizer and fuel are stored in the propellant tank at a low pressure, and a turbo pump is required to pressurize them and supply them to the combustor at a high flow rate.

In addition, the turbo pump pressurizes an oxidizer or fuel through an inducer having spiral blades and an impeller, and a part of the oxidizer or fuel moves through a secondary flow path formed toward the impeller hub and is used for bearing cooling. At this time, a floating ring floating in the secondary passage is provided to adjust the flow rate of the oxidizer or fuel moving into the secondary passage.

However, when the floating ring, which is rotated together by the rotation of the impeller, exceeds a certain number of revolutions under specific operating conditions, strong pressure perturbation and wear due to friction of the surrounding area occur due to the vibration and rotation, which makes the turbo pump stable. There is a problem preventing it from working.

Korean Patent Laid-open Publication No. 10-2020-0140063 ("rotating device", publication date 2020.12.15.)

The present invention has been made to solve the above problems, and an object of the present invention is to provide a floating ring provided in a secondary flow path for cooling bearings in a turbo pump and a floating ring that suppresses excessive rotation by itself through shape deformation of a casing. is to provide

In addition, an object of the present invention is to provide a floating ring that suppresses excessive rotation by itself by providing a plurality of resistors to the floating ring to generate resistance with the working medium in the secondary flow path.

In a rocket engine using a liquid propellant, an impeller for transporting either a liquid oxidant or fuel and a bearing corresponding to an axis of the impeller, a flow path is formed between the impeller hub and an inner casing of the impeller, and the flow path is formed through the flow path. In the turbo pump for cooling the bearing, the turbo pump according to the present invention is provided in the passage and controls the flow rate of liquid oxidant or fuel flowing into the bearing and rotates by itself by at least one of the impeller or the inner casing. It may include a floating ring for inhibiting rotation.

In addition, the floating ring may include an outer surface maintaining a gap with the inner casing, an inner surface maintaining a gap with the impeller hub, and a nose contacting a sidewall of the inner casing.

In addition, the outer surface of the floating ring may include embossing causing friction.

In addition, the inner casing may include a catch that interferes with the embossing as the floating ring moves between rotations of the shaft of the impeller.

In addition, the inner casing may include a groove in which the floating ring interferes with the embossing as the shaft of the impeller moves between rotations.

In addition, the floating ring may cause friction with the inner casing in a form in which an outer diameter changes in a circumferential direction.

In addition, the inner casing may cause friction with the floating ring in a form in which an inner diameter changes in a circumferential direction.

In addition, the inner casing may further include an additional portion.

Also, the floating ring may include a plurality of resistors on an outer surface.

The turbo pump according to the present invention has the advantage of suppressing excessive rotation of the floating ring and preventing unstable pressure fluctuation and wear through deformation of the floating ring provided inside the secondary passage or the inner casing.

In addition, the turbo pump according to the present invention minimizes direct friction between the floating ring and the inner casing, and has the advantage of enabling stable driving of the turbo pump.

1 is a conceptual diagram of a rocket engine equipped with a turbo pump according to the present invention
2 is a cross-sectional view of a turbo pump according to the present invention
3 is an enlarged view of a turbo pump according to the present invention
4 is a cross-sectional view of a turbo pump according to another embodiment of the present invention
5 is a cross-sectional view of a turbo pump according to another embodiment of the present invention
6 is a cross-sectional view of a turbopump according to another embodiment of the present invention
7 is an enlarged view of a turbo pump according to another embodiment of the present invention

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited in their usual or dictionary meanings, and the inventor appropriately defines the concept of terms in order to best describe his/her invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be done.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various modifications that can replace them at the time of the present application It should be understood that there may be examples.

In general, as shown in FIG. 1, a turbo pump is composed of an oxidant pump and a fuel pump for pressurizing and transporting oxidant and fuel, respectively, and a turbine for driving each pump, and includes high-pressure combustion supplied from a gas generator or pre-burner. The turbine is powered by the gas and drives the oxidizer pump and fuel pump.

2 is a cross-sectional view showing an oxidant pump or a fuel pump of a turbo pump 10 according to an embodiment of the present invention. As shown, the turbo pump 10 includes an impeller 200 rotating around an axis. The impeller 200 includes an inducer 230 introducing an oxidizing agent or fuel (A) and an impeller hub 210 determining a transfer direction of the oxidizing agent or fuel (A). At this time, the spiral blade 220 extends from the rear of the inducer 230 to the impeller hub 210, and the oxidizer or fuel A is pressurized and passes through the inducer 230 to the main flow path connected to the propulsion device ( 11) to transfer the oxidizer or fuel (A).

At this time, the oxidizing agent or the fuel (A) may be partially bypassed and used as a lubricant for cooling the bearing 400 . In more detail, as shown, the impeller hub 210 may include a protrusion 211 . The gap between the impeller hub 210 and the protrusion 211 and the inner casing 310 creates a secondary flow path 300 through which the oxidizing agent or fuel A can bypass. It can be used for cooling the bearing 400.

At this time, in order to adjust the flow rate of the oxidant or fuel (A) bypassed through the secondary flow path 300, the inside of the secondary flow path 300, that is, between the inner casing 310 and the impeller hub 210 A floating ring 100 in the form of an annular ring may be provided around the axis of rotation of the impeller.

The floating ring 100 rotates together when the impeller 200 rotates. The floating ring 100 must be in a floating state by fluid force inside the secondary flow path 300 for stable operation. That is, the floating ring 100 preferably maintains a constant gap between the inner casing 310 and the impeller hub 210 when the impeller 200 rotates.

The floating ring 100 can rotate together with the impeller 200 according to the design shape, and when the impeller exceeds a certain number of revolutions, it is synchronized with the vibration and rotation of the impeller, resulting in strong pressure perturbation as well as friction in the periphery. Due to this, abrasion occurs, which causes a problem that prevents the stable operation of the turbo pump 10. On the other hand, if the shape of the floating ring 100 is changed and it is fixed to the wall surface by fluid pressure and cannot rotate, it collides with the rotating impeller and causes other problems such as shock or vibration in the turbo pump 10.

The floating ring 100 according to the present invention for solving the above problems is located in an optimal position in the flow path by the pressure balance of the fluid around the floating ring in the secondary flow path 300 and does not synchronize with the rotation of the impeller. There is an advantage in that instability of the turbo pump 10 due to strong pressure perturbation and vibration caused by the rotation of the floating ring 100 synchronized with and wear of the floating ring 100 can be greatly reduced.

3 is an enlarged view of a part of the secondary flow path 300 of the turbo pump 10 according to the present invention. As shown, the floating ring 100 according to the present invention is suitable for the design of the floating ring nose 101. When the number of revolutions of the impeller 210 increases accordingly, it may come into contact with the sidewall of the inner casing 310 .

More specifically, the turbo pump 10 according to the present invention is a gap formed between the inner casing 310, the impeller hub 210, and the hub protrusion 211, so that the oxidizing agent or fuel (A) A moving secondary passage 300 may be created. The secondary flow path 300 may be provided with a floating ring 100 for adjusting the flow rate of the oxidizing agent or the fuel A. In the flow path 300, the inner and outer surfaces of the floating ring 100 maintain a gap between the impeller 200 and the inner casing 310, that is, maintain a floating state.

In addition, as the rotational speed of the impeller 200 increases, the floating ring 100 rotates together due to friction with the impeller 200 and fluid force. (A) may further include a nose 101 in contact with the sidewall of the inner casing 310 to find and move to an appropriate eccentric position.

At this time, a thin layer formed of an oxidizing agent or fuel A may be formed between the nose 101 and the sidewall of the inner casing 310 .

When the turbo pump 10 operates, the fluid force acting on the floating ring 100 changes according to the size and position of the nose 101, so that the contact pressure between the floating ring 100 and the side wall of the inner casing 310 increases. When the impeller 200 rapidly rotates and vibrates, the floating ring 100 can move in synchronization with the change in position of the impeller 200 in a state of weak contact with the sidewall of the inner casing 310 accordingly. The size and position of the nose 101 should be designed according to the design speed and operating conditions of the turbo pump 10 so that Otherwise, the floating ring 100 may be continuously bumped and damaged due to the vibration of the impeller 200, which may interfere with the operation of the turbo pump 10.

3a and 3b show an embodiment according to the position of the nose 101 of the floating ring 100 according to the present invention, the floating ring 100 according to the present invention is the nose 101 of the floating ring 100 and the radius to the rotational axis of the impeller 200 may have different effects.

More specifically, as shown in FIG. 3A, if the radii of the nose 101 and the impeller 200 to the rotation axis are relatively small, the nose 101 and the nose 101 by the axial fluid force Since the contact pressure at the contact surface between the impellers 200 is relatively small, the mobility of the floating ring 100 by the radial fluid force generated by the vibration of the impeller 200 is increased. Therefore, the floating ring 100, which has a relatively small diameter from the nose 101 to the rotating shaft of the impeller 200, has a low risk of ignition due to continuous friction with the impeller 200, but it is difficult to control the stable posture. As a result, strong pressure perturbations may occur.

On the other hand, as shown in FIG. 3B, if the radius from the nose 101 to the rotation axis of the impeller 200 is relatively large, the contact pressure between the nose 101 and the impeller 200 is relatively large. Therefore, the floating ring 100 strongly contacts the sidewall of the inner casing 310 and the attitude control is stabilized, but due to the friction caused by the vibration of the impeller 200 or the inner casing 310, the floating ring 100 The risk of wear and tear and ignition may increase.

Therefore, in designing the turbo pump 10 according to the present invention, the nose 101 and the sidewall of the inner casing 310 are kept in contact with each other, but the radial direction is appropriately matched to the movement of the impeller 200. Turbo pump 10 according to the present invention to minimize pressure fluctuation and wear by the floating ring 100 by appropriately designing the diameter of the nose 101 and the rotation shaft of the impeller 200 to facilitate movement It is desirable to design

Figure 4 is a cross-sectional view through the floating ring of the turbo pump 10 according to another embodiment of the present invention, the turbo pump 10 according to the present invention is the embossing 110 and the latch 311 that interfere with each other can include more.

More specifically, the floating ring 100 according to the present invention rotates together with the rotation of the impeller 200, and at this time, the rotational axis of the floating ring 100 is separated from the rotational axis of the impeller 200. will repeat Using this phenomenon, the floating ring 100 according to the present invention includes an embossing 110 protruding on the outer surface adjacent to the inner casing 310, and the inner casing 310 adjacent to the floating ring 100. The inner surface may include a latch 311 that the embossing 110 continuously takes. As such, in the turbo pump 10 according to the present invention including the embossing 110 and the catch 311, the embossing 110 and the catch 311 move as the rotating shaft of the floating ring 100 moves. They interfere with each other, which reduces the number of revolutions and has the effect of preventing pressure fluctuations caused by over-rotation.

5 is a cross-sectional view through the floating ring of the turbo pump 10 according to another embodiment of the present invention, the inner casing 310 of the turbo pump 10 according to the present invention further has a groove 313 can include

More specifically, the floating ring 100 according to the present invention rotates together with the rotation of the impeller 200, and at this time, the rotational axis of the floating ring 100 is separated from the rotational axis of the impeller 200. will repeat Using this phenomenon, the floating ring 100 according to the present invention includes an embossing 110 protruding on the outer surface adjacent to the inner casing 310, and the inner casing 310 adjacent to the floating ring 100. The inner surface may further include a groove 313 dug so that the embossing 110 continuously takes. The groove 313 may be formed in a shape dug outward from an inner surface of the inner casing 310 . Alternatively, as shown, a plurality of protrusions 314 may be formed on the inner surface of the inner casing 310, and grooves 313 may be formed between the protrusions 314. As described above, in the turbo pump 10 according to the present invention including the embossing 110 and the groove 313, the embossing 110 and the groove 313 move as the rotating shaft of the floating ring 100 moves. They interfere with each other, which reduces the number of revolutions and has the effect of preventing pressure fluctuations caused by over-rotation.

6 is a cross-sectional view through the floating ring of the turbo pump 10 according to another embodiment of the present invention, the outer diameter and the inner casing of the floating ring 100 in contact with each other of the turbo pump 10 according to the present invention The inner diameter of 310 may be formed in a form in which the radius of curvature changes in the circumferential direction of the center of the rotation axis of the impeller 200 .

In more detail, at least one of the floating ring 100 and the inner casing 310 according to the present invention is connected to the outer surface of the floating ring 100 and the inner casing 310 while the floating ring 100 rotates. The outer diameter of the floating ring 100 and the inner diameter of the inner casing 310 may be formed in a form in which the radius of curvature changes in the circumferential direction so that the inner surface of the outer diameter of the floating ring 100 may interfere with each other. In other words, when the rotating shaft of the floating ring 100 rotates while repeating separation from the rotating shaft of the impeller 200, the outer diameter of the floating ring 100 and the inner diameter of the inner casing 310 are irregular in radius of curvature. Due to this, the outer surface of the floating ring 100 and the inner surface of the inner casing 310 may periodically cause friction. Accordingly, as shown, a portion of the floating ring 100 may be made thicker toward the inner casing 310 . Also, as shown, a portion of the inner casing 310 toward the floating ring 100 may be made thicker. For example, the inner casing 310 may further include an additional portion 312 that changes its inner diameter in the circumferential direction. At this time, the padding part 312 may be manufactured in a form in which a member made of the same material as the inner casing 310 is attached and welded, or a member made of a material having a greater frictional force than the material of the inner casing 310 is attached. .

Therefore, the floating ring 100 has an effect of preventing pressure fluctuations caused by over-rotation by continuously reducing its rotational speed.

FIG. 7 shows a turbo pump 10 according to another embodiment of the present invention. As shown in FIG. 7, the floating ring 100 according to the present invention has a plurality of outer surfaces adjacent to the inner casing 310. A resistor 120 of may be further included.

More specifically, the floating ring 100 may include a plurality of resistors 120 having a surface area perpendicular to the rotational direction of the floating ring 100 on an outer surface. At this time, in order to prevent excessive friction with the inner casing 310, the resistor 120 may be manufactured in a round outer portion adjacent to the inner casing 310.

In this way, the floating ring 100 includes the plurality of resistors 120, thereby causing resistance with the oxidizer or fuel (A) between rotations of the impeller 200 to reduce the number of revolutions and pressure generated by over-rotation. It has the effect of preventing perturbation.

10: turbo pump
11: main flow path A: working medium
100: floating ring
101: nose
110: embossing 120: resistor
200: impeller
210: impeller hub 211: hub protrusion
220: blade 230: inducer
300: 2nd Euro
310: inner casing 311: latch
312: padding 313: groove
314: chin
400: bearing

Claims (9)

An impeller for transporting either liquid oxidizer or fuel in a rocket engine using liquid propellant; and
a bearing corresponding to the shaft of the impeller;
In the turbo pump comprising a, forming a flow path with the impeller hub and the inner casing of the impeller and cooling the bearing through the flow path,
a floating ring for inhibiting rotation provided in the passage and controlling the flow rate of liquid oxidant or fuel flowing into the bearing and inhibiting rotation by itself by at least one of the impeller or the inner casing;
including,
The floating ring may include an outer surface maintaining a gap with the inner casing;
an inner surface maintaining a gap with the impeller hub; and
a nose contacting the inner casing sidewall;
A turbopump comprising a.
delete According to claim 1,
The outer surface of the floating ring includes an embossing that causes friction.
According to claim 3,
The inner casing is a turbo pump, characterized in that the floating ring comprises a catch that interferes with the embossing as the shaft of the impeller moves between rotations.
According to claim 3,
The inner casing includes a groove in which the floating ring interferes with the embossing as the shaft of the impeller moves between rotations.
According to claim 1,
The turbopump, characterized in that the floating ring causes friction with the inner casing in a form in which the outer diameter changes in the circumferential direction.
According to claim 6,
The inner casing causes friction with the floating ring in a form in which an inner diameter changes in a circumferential direction.
According to claim 7,
The turbo pump, characterized in that the inner casing further comprises an additional portion.
The method of any one of claims 1, 3 to 8,
The turbopump, characterized in that the floating ring comprises a plurality of resistors on the outer surface.

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