KR20130055921A - Oil mist reduction device - Google Patents

Abstract

PURPOSE: An oil mist leakage reduction device is provided to prevent oil mist from being leaked by installing a check valve and an electric motor when a turbine generator is stopped for regularly maintaining the inside pressure of a bearing housing. CONSTITUTION: An oil mist leakage reduction device comprises a bearing housing(100), an air inlet pipe(200), an oil mist outlet pipe(220), a first pipe(310), a tee(300), and a sealing part(600). The tee divides a second pipe(311) which is equipped one tip end of the air inlet pipe. The sealing part comprises a brush seal(611) inside the upper cover of the bearing housing and a labyrinth seal(610) in a rotator(20) in order to prevent the leakage of the oil mist. [Reference numerals] (500) Oil mist separator; (510) Air filter; (AA) External air; (BB,CC) Oil mist

Description

Oil mist reduction device

The present invention relates to an oil mist leakage reduction device, and to block oil mist generated from a bearing of a rotor generator, internal air injection from the outside in accordance with the pressure distribution inside the generator at the time of starting and stopping the generator. An oil mist spill reduction device for preventing oil from leaking out by keeping pressure constant.

In general, the bearing housing is installed on the outer periphery of the shaft in order to discharge heat generated during the shaft rotation of the generator to the outside, and is provided to cool the heat generated when the shaft rotates through the cooling water or the cooling oil in the bearing housing.

However, as the oil temperature in the bearing housing rises around the rotating shaft, a problem arises in that it leaks into the housing gap.

Therefore, in order to prevent the oil spill, a felt seal or another oil seal is used.

However, as the oil temperature rises, the seal is damaged, which causes the hassle of frequent replacement.

With the technique similar to the above, the utility model registration 20-0303970 proposed a dust and oil leakage prevention structure of the bearing, and the above technique is a bearing is installed inside the bearing housing, the bearing is rotated by the rotating shaft is mounted And a through hole of the ring is in close contact with a rotating shaft located in an upward direction of the bearing so that the circumferential portion of the ring is in intimate contact or finely spaced contact with the inner circumferential wall of the bearing housing to prevent dust and oil leakage of the bearing. .

However, the above technique may be worn by friction during rotation of the ring due to pinching of heat or foreign substances generated when the ring rotates, and a problem of frequently replacing the ring in a certain period of time occurs.

In addition, there is a problem that the wear phenomenon due to rotation frequently occurs by using an oil seal or an oil prevention gasket in order to prevent the oil in the water turbine generator that is currently used.

The present invention is to solve the above problems, while the clean air is supplied from a separate air supply device to replace the air seal function while the oil temperature in the bearing housing is above a certain value in a state in which the rotor of the water turbine generator is stopped. It provides an object to prevent the fine air particles such as oil mist generated in the bearing housing to leak to the outside.

In addition, when the water turbine generator is stopped, the purpose of the oil vapor is to install a check valve and an electric motor to maintain a constant pressure in the bearing housing so that the oil mist does not leak.

In addition, it is intended to reduce the outflow of air from the outside by installing a brush seal, and to be introduced into the bearing housing to be introduced into the Labyrinth Seal.

The present invention for achieving the above object contains the oil for the lubrication between the rotor 20 and the bearing portion of the aberration generator, it is composed of a double bearing housing 100 which is finished with the upper cover 110 ); An air inlet pipe 200 provided to supply external air between the bearing housing 100 and an upper side of the bearing housing 100 between the outer cover 120 and the inner cover 121; An oil vapor discharge pipe (220) provided on an outer circumferential surface of the bearing housing (100) to cover oil vapor generated in the bearing housing (100); "T" type pipe 300 for dividing the first pipe 310 provided on one end of the air inlet pipe 200 and the second pipe 311 provided on one end of the air inlet pipe 200. ; Labyrinth Seal 610 provided in the Brush Seal 611 and the rotating body 20 on the inner surface of the upper cover 110 of the bearing housing 100 so that oil mist generated in the bearing housing 100 does not leak out. The sealing unit 600 is provided; Characterized in that configured to include.

In addition, the air inlet pipe 200 is characterized in that the flow rate control valve 210 for adjusting the amount of air on one side.

In addition, the oil vapor discharge pipe 220 is characterized in that the oil vapor separator 500 and the air filter 510 for separating the oil component of the oil vapor discharged from the inside of the bearing housing 100 on one side.

In addition, the compression generated by the rotation of the rotating body 20 to block the oil vapor generated in the bearing housing 100 to flow out of the gap between the upper cover 110 and the rotating body 20 of the bearing housing 100. Air is supplied to the second pipe 311 and the air inlet pipe 200 through the lower chamber 31, but when the air supply is stopped through the second pipe 311 in accordance with the stop of the rotating body 20 Air supply 400 is provided at one end of the first tube 310 to be separated from the "T" type tube 300 to be supplied.

In addition, a first check valve 330 is provided to prevent oil vapor from flowing into the air fan 400 through the first pipe 310 when the rotating body 20 is stopped, and the second pipe 311 is provided. A second check valve 331 is provided so that oil vapor does not flow into the lower chamber 31 through).

In addition, a brush seal 611 is provided on an inner surface of the outer cover 110 of the bearing housing 100, and the resistance of the air flow is increased by a gap between the rotating body 20 and the outer cover 120 of the bearing housing 100. , The clean air supplied from the air inlet pipe 200 through the gap between the Labyrinth Seal 610 and the inner cover 121 of the bearing housing 100 provided in the rotating body 20 than the gap of the outer cover 120 Inflow into the housing 100 to allow the oil vapor in the bearing housing 100 to flow out of the oil vapor discharge pipe 220, thereby blocking the oil vapor flowing out into the gap of the inner cover 121 of the bearing housing 100. Characterized in that.

According to the present invention has the following effects.

First, the oil mist generated in the bearing housing to replace the air seal function by receiving clean air from a separate air supply device while the oil temperature in the bearing housing is above a certain level while the rotor of the water turbine generator is stopped. It provides an effect that prevents the leakage of fine air particles to the outside.

Second, when the water turbine generator is stopped, oil vapor is provided with a check valve and an electric motor to maintain a constant pressure in the bearing housing so that oil mist does not leak out.

In addition, by installing a brush seal to reduce the inflow of air from the outside to the outside, to be introduced into the Labyrinth Seal to the inside of the bearing housing provides an effect of lowering the internal temperature efficiently.

1 is an air flow diagram when the water turbine generator is stopped for the oil mist leakage reducing apparatus of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1 is an air flow diagram when the water turbine generator of the present invention is stopped.

The configuration and the coupling relationship of the present invention will be described with reference to the respective drawings.

Reduction device 10 of the present invention is a rotor 20, a top chamber 30 surrounding the top of the rotor 20, a lower chamber 31 provided below the rotor, the rotor Bearing housing 100 surrounding the 20, the upper cover 110 and the outer cover 120, the inner cover 121 for closing the upper portion of the bearing housing 100.

In addition, the bearing housing 100 is provided with an air inlet pipe 200 for introducing air from the outside on the upper side, the air inlet pipe 200 on one side of the flow control valve 210, "T" type pipe ( 300, a first pipe 310, a second pipe 311, an electric valve 320, a first check valve 330, a second check valve 331, and an air fan 400.

In addition, an oil vapor discharge pipe 220 for discharging oil vapor in the bearing housing 100 is provided at one side of the bearing housing 100 on an outer circumferential surface thereof, and an oil vapor separator 500 and an air filter 510 are disposed at one side of the oil vapor discharge pipe 220. It is provided with a sealing portion 600 provided with a Labyrinth Seal 610, a Brush Seal 611 on one side in the bearing housing 100 so that the oil mist in the bearing housing 100 does not leak to the outside.

As shown in Figure 1, the bearing housing 100 containing the oil for lubrication between the rotor 20 and the bearing portion of the aberration generator of the present invention, a double configuration is finished with the upper cover 110 ; An air inlet pipe 200 provided to supply external air between the bearing housing 100 and an upper side of the bearing housing 100 between the outer cover 120 and the inner cover 121; An oil vapor discharge pipe (220) provided on an outer circumferential surface of the bearing housing (100) to cover oil vapor generated in the bearing housing (100); "T" type pipe 300 for dividing the first pipe 310 provided on one end of the air inlet pipe 200 and the second pipe 311 provided on one end of the air inlet pipe 200. ; Labyrinth Seal 610 provided in the Brush Seal 611 and the rotating body 20 on the inner surface of the upper cover 110 of the bearing housing 100 so that oil mist generated in the bearing housing 100 does not leak out. The sealing unit 600 is provided; Characterized in that configured to include.

In addition, a flow control valve 210 for controlling the amount of air on one side of the air inlet pipe 200 is provided.

In addition, an oil vapor separator 500 and an air filter 510 for separating oil components of oil vapor discharged from the inside of the bearing housing 100 are provided at one side of the oil vapor discharge pipe 220, and are generated in the bearing housing 100. The second pipe through the lower chamber 31 through the lower chamber 31, the compressed air generated by the rotation of the rotor 20 in order to prevent the oil vapor from flowing into the gap between the bearing housing 100, the upper cover 110 and the rotor 20 311 and the air inlet pipe 200, but the "T" type pipe 300 to enable the air supply when the air supply is interrupted through the second pipe 311 in accordance with the rotating body 20 is stopped. Air fan 400 is provided at one end of the first tube 310 to be separated from.

In addition, a first check valve 330 is provided to prevent oil vapor from flowing into the air fan 400 through the first pipe 310 when the rotating body 20 is stopped, and the second pipe 311 is provided. The second check valve 331 is provided so that oil vapor does not flow into the lower chamber 31 through).

In addition, a brush seal 611 is provided on an inner surface of the outer cover 110 of the bearing housing 100, and the resistance of the air flow is increased by a gap between the rotating body 20 and the outer cover 120 of the bearing housing 100. , The clean air supplied from the air inlet pipe 200 through the gap between the Labyrinth Seal 610 and the inner cover 121 of the bearing housing 100 provided in the rotating body 20 than the gap of the outer cover 120 Inflow into the housing 100 to allow the oil vapor in the bearing housing 100 to flow out of the oil vapor discharge pipe 220, thereby blocking the oil vapor flowing out into the gap of the inner cover 121 of the bearing housing 100. It consists of doing

As shown in the figure, it will be described in detail as follows.

The bearing housing 100 of the present invention has a dual structure in which the rotating body 20 is coupled, and the dual structure includes an outer cover 120 and an inner cover 121.

The rotating body 20 direction of the bearing housing 100 is a space into which external air flows.

Therefore, the external space is introduced to prevent the backflow of oil vapor when the water turbine generator is stopped.

In addition, the sealing unit 600 is provided to prevent the outflow of the oil vapor into the space in which the outside air flows, and to reduce the outflow to the outside of the bearing housing 100 when the outside air inflow.

The sealing part 600 is provided with a labyrinth seal 610 and a brush seal 611, and the brush seal 611 is provided with a bearing housing 100 to prevent external air from leaking out of the bearing housing 100. It is made to be provided on the inner surface of the outer cover (120).

In addition, the Labyrinth Seal 610 is coupled to the rotating body 20 so that oil outside the bearing housing 100 does not flow out to the other side of the Brush Seal 611 and only the outside air flows in.

In addition, an air inlet pipe 200 is provided on the bearing housing 100 in order to introduce external air into the space of the bearing housing 100 formed in a double structure, and the outside air is provided along the air inlet pipe 200. The inflow is as shown in the figure.

The flow control valve 210 is provided to adjust the amount of air introduced into one side of the air inlet pipe 200, the flow control valve 210 is made to operate according to the control unit provided on the outside.

In addition, the "T" type pipe 300 is coupled to the one-way air inlet pipe 200 of the flow control valve 210, the first pipe 310 on the upper side of the "T" type pipe 300 ) Is provided, and the second tube 311 is provided at one side.

In addition, only a portion of the first pipe 310 is introduced into the air from the outside, and the first check valve 330 is provided so that the incoming air does not flow back, the second pipe 311 is also part of the first Like the first pipe 310, the second check valve 331 is provided.

In addition, a portion of the first tube 310 is provided with an electric valve 320, the air pipe 400 for introducing air into the first tube 310 is provided.

Therefore, the amount of air flowing into the first pipe 310 is operated by the controller provided in the outside in accordance with the situation in the electric valve 320.

In addition, one end of the second pipe 311 is connected to the lower chamber, the air generated by the rotation of the rotating body is moved to the air inlet pipe (200).

As shown in the figure, the oil vapor discharge pipe 200 is provided for discharging oil vapor generated in the bearing housing 100, it is provided on one outer peripheral surface of the bearing housing 100.

One end of the vapor discharge pipe 220 is provided with a vapor separator 500, is separated from the vapor separator 500, the steam generated after separation is discharged by the filter by the air filter 510.

In addition, a second check valve 331 is provided so that oil vapor in the bearing housing 100 does not flow into the lower chamber 31 through the second pipe 311 when the rotating body 20 is stopped. The air fan 400 provided at 310 operates to introduce air into the bearing housing 100 so that oil vapor is discharged through the oil vapor discharge pipe 220.

As described above, the combination and configuration of the configuration of the present invention has been described, and the flow for the external air and the vapor will be described with reference to the arrows shown in the drawings as follows.

As shown in Fig. 1, the dashed arrows indicate oil vapor, and the solid arrows indicate external air.

In addition, the pressure of each position is shown by P1, P2, P3, P4, P5.

According to the present invention, the oil vapor is discharged through the oil vapor discharge pipe 220 as the temperature of the oil in the bearing housing 100 surrounding the rotor 20 increases due to the rotation of the rotor generator 20.

In addition, in order to prevent a phenomenon in which oil vapor flows back into the air inlet pipe 200 when the water turbine generator is stopped, air is introduced into the air fan 400 provided outside.

Therefore, the oil vapor generated in the bearing housing 100 is discharged along the oil vapor discharge pipe 220 without being leaked to the outside.

In addition, by injecting air as described above, the exchange cycle of the Brush Seal 611 and the Labyrinth Seal 610 is to provide an effect that the oil ring or oil seal is used more than conventional.

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. Accordingly, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

10: reduction device 20: rotating body
30: upper chamber 31: lower chamber
100: bearing housing 110: upper cover
120: outer cover 121: inner cover
200: air inlet pipe 210: flow control valve
220: vapor discharge pipe
300: "T" type tube 310: first tube
311: 2nd pipe 320: electric valve
330: first check valve 331: second check valve
400: air fan
500: vapor separator 510: air filter
600: sealing part 610: Labyrinth Seal
611: Brush Seal

Claims (6)

A bearing housing 100 containing oil for lubricating action between the rotor 20 and the bearing part of the aberration generator, which is dually formed and finished with the upper cover 110;
An air inlet pipe 200 provided to supply external air between the bearing housing 100 and an upper side of the bearing housing 100 between the outer cover 120 and the inner cover 121;
An oil vapor discharge pipe (220) provided on an outer circumferential surface of the bearing housing (100) to cover oil vapor generated in the bearing housing (100);
A first pipe 310 provided above the one end of the air inlet pipe 200 and
"T" type pipe 300 for dividing the second pipe 311 is provided at one end of the air inlet pipe 200;
Labyrinth Seal 610 provided in the Brush Seal 611 and the rotating body 20 on the inner surface of the upper cover 110 of the bearing housing 100 so that oil mist generated in the bearing housing 100 does not leak out. The sealing unit 600 is provided;
Oil mist spill reduction device, characterized in that configured to include.
The method of claim 1,
Oil mist outflow reduction device, characterized in that the air inlet pipe 200 is provided with a flow control valve 210 for adjusting the air amount on one side.
The method of claim 1,
Oil mist discharge reduction device, characterized in that the oil vapor discharge pipe 220 is provided with a vapor separator (500) and an air filter (510) for separating the oil component of the oil vapor discharged from the inside of the bearing housing (100) on one side.
The method of claim 1,
Compressed air generated by the rotation of the rotor 20 to block oil vapor generated in the bearing housing 100 from leaking into the gap between the upper cover 110 and the rotor 20 of the bearing housing 100. While supplying to the second pipe 311 and the air inlet pipe 200 through the lower chamber 31, the air supply is stopped when the air supply is stopped through the second pipe 311 in accordance with the stop of the rotating body (20) Oil mist spill reduction device, characterized in that the air fan 400 is provided at one end of the first tube 310 to be separated from the "T" type tube 300 to enable.
The method of claim 1,
A first check valve 330 is provided to prevent oil vapor from flowing into the air fan 400 through the first pipe 310 when the rotating body 20 is stopped, and the second pipe 311 is provided. Oil mist outflow reduction device, characterized in that the second check valve 331 is provided so that oil vapor does not flow into the lower chamber (31) through.
The method of claim 1,
A brush seal 611 is provided on the inner surface of the outer cover 110 of the bearing housing 100, and the resistance of the air flow is increased by a gap between the rotating body 20 and the outer cover 120 of the bearing housing 100, and air The clean air supplied from the inlet pipe 200 is formed through the gap between the Labyrinth Seal 610 and the inner cover 121 of the bearing housing 100 provided in the rotor 20 rather than the gap between the outer cover 120 and the bearing housing ( 100) is introduced into the inside of the bearing housing 100 to allow the oil vapor to flow into the discharge pipe 220, to prevent the oil vapor from leaking into the gap of the inner cover 121 of the bearing housing 100 in advance. Oil mist spill reduction device characterized in that.

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