KR20130053581A - Bearing cooling unit with forced circulation flow line and liquid fuel pump including the unit - Google Patents

Abstract

PURPOSE: A bearing cooling device including a forced circulating passage and a liquid fuel pump with the same are provided to stably cool a bearing with refrigerant of high pressure. CONSTITUTION: A bearing cooling device including a forced circulating passage comprises a first circulating passage(30), a second circulating passage(35), and a cover(60). The first circulating passage is installed in the outside of the case and delivers materials flowing in through a cooling medium inlet to a cooling medium outlet. The second circulating passage is formed inside a bearing supporting unit and delivers the material being discharged to the bearing. The cover closes the bearings.

Description

Bearing cooling unit including a forced circulation path and a liquid fuel pump including the bearing cooling device {Bearing cooling unit with forced circulation flow line and liquid fuel pump including the unit}

The present invention relates to a cooling device for cooling a bearing supported by a bearing support installed in an inner space of a case for delivering an arbitrary material, and in particular, by installing a circulation path outside the case and supplying the inside of the case. It relates to a bearing cooling device for cooling the bearing by forcibly feeding back.

Inducers used in centrifugal pumps are spiral rotating structures (propellers) installed in front of impellers with wings used to mix the supplied liquid. This is to improve the suction performance of the impeller.

1 is a cross-sectional view of a conventional fluid transfer pump.

2 shows the inducer inserted in the axis of rotation.

3 shows an impeller installed at the rear end of the inducer.

Referring to FIG. 1, the fluid transfer pump includes an inducer 100, a rotation shaft 200, a case 300, a bearing support 400, and a bearing 500.

The inducer 100 is helically coupled to the outer diameter of the rotating shaft 200 to transfer the liquid sucked from the front to the impeller (Fig. 3) installed in the rear. The bearing 500 supporting the rotating shaft 200 is fixed in position by the bearing support 400. The bearing 500 supporting the rotation of the rotary shaft 200 is naturally cooled by the flow flowing into the inducer 100 inlet.

Referring to FIG. 1, the flow of liquid in the conventional fluid transfer pump 100 is illustrated by an arrow, and the liquid flowing to the central portion cools the bearing 500 while passing through the bearing 500.

As the inducer 100 rotates, a lot of heat is generated in the bearing 500, and cooling oil must be continuously supplied to cool the bearing 500 supporting the rotating shaft of the inducer 100. High-performance pumps, such as turbopumps for liquid rocket engines, operate in extreme environments, such as high speed and low pressure, and replace cooling of bearings that support the rotating shaft with hydraulic fluid. Here, the working oil means liquid fuel or liquid oxygen to be delivered from the fluid transfer pump 100.

At this time, when the hydraulic oil flows into the bearing 500 at a very low pressure, the cooling of the bearing 500 is not sufficient because the vaporization of the hydraulic oil occurs in the heated bearing 500. Insufficient cooling of the bearing 500 leads to premature failure of the bearing 500.

The technical problem to be solved by the present invention is to install a circulation path on the outside of the case to cool the bearing supported by the bearing support installed in the inner space of the case for transferring any material, the material supplied into the case It is to provide a bearing cooling device for cooling the bearing by forcibly feeding back.

Another technical problem to be solved by the present invention is to provide a circulation path to the outside of the case to cool the bearing supported by the bearing support installed in the inner space of the case for transferring any material, which is supplied to the inside of the case A liquid fuel pump having a bearing cooling device for forcibly feeding back a material to cool the bearing.

Bearing cooling apparatus including a forced circulation circuit according to an embodiment of the present invention for achieving the above technical problem, the bearing is supported by the bearing support installed in the inner space of the case for transferring any material, the first A circulation path, a second circulation path and a cover are provided. The first circulation path is installed outside the case and transfers the material introduced from the cooling medium inlet to the cooling medium outlet. The second circulation path is formed inside the bearing support, and transfers the material flowing out of the cooling medium outlet to the bearing. The cover seals the bearing.

Liquid fuel pump according to an embodiment of the present invention for achieving the above another technical problem, a case, a bearing support, bearings, a rotating shaft, the first circulation path, the second circulation path and the cover is provided. The case delivers any material, and a coolant outlet and a coolant inlet are respectively formed outside. The bearing support is installed in the inner space of the case. The bearing is supported by the bearing support. The axis of rotation rotates along the bearing. The first circulation path is installed outside the case and is formed between the refrigerant outlet and the refrigerant inlet. The second circulation path is formed in the bearing support, and transfers the material flowing out of the refrigerant inlet to the bearing. The cover seals the bearing.

Cooling the bearing by providing a circulation path of the coolant on the outside of the case by forcibly circulating the fluid behind the high-pressure inducer, it is possible to reliably cool the bearing using the high-pressure refrigerant.

In addition, since the cooling flow of the inducer rises more at high flow, the inducer's performance and stability can be attained because the inducer's abrupt deterioration at low flow and the side effect of delaying vibration such as surge can be obtained. Can increase.

1 is a cross-sectional view of a conventional fluid transfer pump.
2 shows the inducer inserted in the axis of rotation.
3 shows an impeller installed at the rear end of the inducer.
4 is a cross-sectional view of a bearing cooling apparatus including a forced circulation path according to the present invention.

In order to fully understand the present invention and the operational advantages of the present invention and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings, which are provided for explaining exemplary embodiments of the present invention, and the contents of the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

4 is a cross-sectional view of a bearing cooling apparatus including a forced circulation path according to the present invention.

Referring to FIG. 4, the bearing cooling apparatus according to the present invention cools the bearings 500 supported by the bearing support part 400 installed in the inner space of the case 300 for transferring any material, and the first The circulation path 30, the 2nd circulation path 35, and the cover 60 are provided.

The first circulation path 30 is installed outside the case 300, and transfers the material introduced from the cooling medium inlet 10 to the cooling medium outlet 20. The material here is the material the bearing chiller is intended to deliver, for example, it can be either liquid fuel or liquid oxygen. The second circulation path 35 is formed in the bearing support 400, and transfers the material flowing out of the cooling medium outlet 20 to the bearing 500.

The cover 60 is installed in a direction in which the material is first contacted with the case 300 and sealed to seal the bearing 500 to the refrigerant flowing through the first circulation path 30 and the second circulation path 35. Only by cooling.

In the middle of the first circulation path 30, a control device 50 for adjusting the amount of material delivered along the first circulation path 30 is installed, the control device 50 is provided with an orifice 51 through which the fluid passes It is formed more.

According to the operation of the inducer 100 and the pump (not shown) behind the impeller (not shown), the material flowing into the inducer 100 is moved to the place to be delivered through the impeller (not shown). Referring to FIG. 4, the pressure of the right part of the inducer 100 is higher than that of the left side of the bearing 500. Therefore, the material located in the right space 5 of the bearing 500 is transferred to the bearing 500 through the cooling medium inlet 10 and the cooling medium outlet 20, where the supply pressure of the material is shown in FIG. 1. Since it is higher than the case, since the vaporization does not occur easily, the effect of cooling becomes relatively large.

Therefore, the amount of the material flowing through the circulation paths 30 and 35 is proportional to the pressure difference between the front and the rear of the inducer 100 and is inversely proportional to the resistance of the circulation paths 30 and 35. When the resistance of the circulation paths 30 and 35 is constant, the amount of circulating material used as the refrigerant increases at a low flow rate where the head of the inducer 100 is large, that is, the pressure difference between the front and the back of the inducer is large.

In the case of low flow rate, the flow rate of the circulation paths 30 and 35 increases due to the large pressure difference, so that the inflow of the inductor 100 is close to the proper flow rate, so that the reverse flow and surge at low flow rate are delayed.

At this time, by using the control device 50 formed with a small size of the orifice 51 can be adjusted to flow less of the circulating material at the design flow rate and high flow rate.

Referring to the solid arrow indicating the path of the cooling material movement, the cooling material in the space 5 passes through the bearing 500 through the first circulation path 30 and the second circulation path 35 and is again inside. Return to space 5. Dotted lines indicate the transmission path of the substance, liquid fuel or liquid oxygen.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

10: cooling medium inlet 20: cooling medium outlet
30: first circulation passage 35: second circulation passage
40: coupling sphere 50: control sphere
51: orifice 60: cover
100: inducer 200: axis of rotation
300: case 400: bearing support
500: bearing

Claims (2)

In the bearing chiller for cooling a bearing supported by a bearing support installed in the inner space of the case for transferring any material,
A first circulation path installed outside the case and transferring the material introduced from the cooling medium inlet to the cooling medium outlet;
A second circulation path formed in the bearing support and configured to transfer the material flowing out of the cooling medium outlet to the bearings; And
Bearing cooling apparatus comprising a forced circulation path characterized in that it has a cover for sealing the bearings.
A case for transferring any material and having a refrigerant outlet and a refrigerant inlet respectively formed therein;
A bearing support installed in the inner space of the case;
Bearings supported by the bearing support;
A rotating shaft rotating along the bearings;
A first circulation path disposed outside the case and formed between the refrigerant outlet and the refrigerant inlet;
A second circulation path formed in the bearing support and configured to transfer the material flowing out of the refrigerant inlet to the bearings; And
And a cover for sealing the bearings.

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