KR20170062652A - Cooling device for rotating shaft - Google Patents

Abstract

The oil pump includes a rotary shaft, a bearing rotatably supporting the rotary shaft, an oil ring inserted in the bearing and rotated in association with the rotary shaft, a reservoir in which oil is stored so that the lower end of the oil ring is locked, An oil outflow pipe connected to the reservoir and allowing the oil to flow out from the reservoir; a flow meter installed in at least one of the oil inflow pipe and the oil outflow pipe; And a valve for controlling the amount of oil flowing in and out of the river bed.

Description

Technical Field [0001] The present invention relates to a cooling device for a rotating shaft,

The present invention relates to a rotary shaft cooling apparatus.

Generally, the rotary device is provided with a rotary shaft for rotating and a bearing for fixing the rotary shaft. Oil is injected to reduce friction between the rotating shaft and the bearing and to cool it.

The injected oil flows to the reservoir under the bearing and circulates through the pipe connected to the reservoir.

On the other hand, the rotating device can operate at a temperature higher than the designed operating temperature due to the difference in manufacturing environment and operating environment. To lower the temperature, more oil inflow is required, and if it exceeds a certain amount, it leads to the oil leakage problem.

Even if the designed inflow amount is used, the oil level changes due to the manufacturing error, the installed environment, and the viscosity of the oil to be used, leading to a leakage problem.

Conventionally, there has been used a method of leaving a certain amount of leakage, adjusting the inflow amount of the oil through an empirical method, or enhancing the function of the seal to prevent leakage. However, this method makes it difficult to find inflows that can not be leaked and needs to be adjusted whenever the environment changes.

Therefore, it is necessary to develop a structure capable of adjusting the oil inflow amount while solving the oil leakage problem.

Korea Patent Publication No. 2012-0003205

There is provided a rotary shaft cooling device capable of adjusting the amount of storage of cooling oil.

According to an aspect of the present invention, there is provided a rotary shaft cooling apparatus including a rotary shaft, a bearing rotatably supporting the rotary shaft, an oil ring inserted in the bearing and rotated in conjunction with the rotary shaft, An oil outflow pipe connected to the reservoir to allow the oil to flow out from the reservoir, and an oil outflow pipe connected to the reservoir, wherein the oil outflow pipe is connected to the reservoir, A flow meter installed in at least one of the oil outflow pipes, and a valve for regulating the amount of oil flowing in and out of the river reservoir.

The reservoir may have a drain hole through which the auxiliary outlet pipe is connected to the bottom surface, and the valve may be installed in the auxiliary outlet pipe.

The valve may be connected to an oil level regulator for regulating opening and closing of the valve in accordance with flow rate information from the flow meter.

The valve may include a first valve installed in the oil inlet pipe and a second valve installed in the oil outlet pipe.

The first valve and the second valve may be connected to an oil level controller.

The storage amount of the cooling oil can be controlled.

1 is a schematic block diagram of a rotating shaft cooling apparatus according to an embodiment of the present invention.
2 is a schematic block diagram of a rotating shaft cooling apparatus according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

1 is a schematic block diagram of a rotating shaft cooling apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a rotary shaft cooling apparatus 100 according to an embodiment of the present invention includes a rotary shaft 110, a bearing 120, an oil ring 130, a reservoir 140, an oil inlet pipe 150 An oil outflow pipe 160, a flow meter 170, an auxiliary outlet pipe 180, a valve 190, and an oil level regulator 200.

The rotating shaft 110 is rotatably installed in a main body of the apparatus (not shown) to transmit rotational force.

A bearing mounting plate 112 for mounting the bearing 120 may be formed on the rotating shaft 110. Further, at the rear end of the bearing mounting plate 112, a seal forming member 102 for forming a lever rinse seal for suppressing oil leakage may be provided.

The bearing 120 rotatably supports the rotary shaft 110. That is, the bearing 120 may have a substantially hollow cylindrical shape so that the rotating shaft 110 is installed to pass therethrough. The bearing 120 may be formed with a through hole 122 through which the oil ring 130 rotates in conjunction with the rotation shaft 110.

The oil ring 130 is installed to penetrate the through hole 122 of the bearing 120 and is rotated in conjunction with the rotation shaft 110. The oil ring 130 is arranged so that the lower end of the oil ring 130 is locked to the oil stored in the reservoir 140.

Since the oil ring 130 rotates in conjunction with the rotation shaft 110 and the lower end of the oil ring 130 is arranged to be submerged in the oil, the oil is supplied to the bearing 120 and the rotation shaft 110 to cool the heat generated by the friction between the bearing 120 and the rotary shaft 110.

The reservoir 140 serves to store the oil so that the lower end of the oil ring 130 is locked. The reservoir 140 may be fixed to the apparatus body (not shown), and a reservoir groove (not shown) may be formed in the reservoir 140 to receive the lower end of the rotation shaft 110.

Further, the reservoir 140 may have an inner space and an open top shape so as to store the oil.

An inlet hole (not shown) and an outlet hole 142 in which the oil inlet pipe 150 and the oil outlet pipe 160 are installed may be formed in the reservoir 140. The outlet hole 142 is formed to have the same height as the oil level stored in the preset reservoir 140.

That is, the outlet hole 142 is formed in the reservoir 140 so as to be disposed at the same position as the predetermined water level so as to prevent the oil level from becoming lower than a certain level.

A drain hole 144 may be formed at the bottom of the reservoir 140 for installing the auxiliary outlet pipe 180.

The oil inlet pipe 150 is connected to the reservoir 140 so that the oil flows into the reservoir 140. That is, the oil inlet pipe 150 is installed in the inlet hole formed at the upper end of the reservoir 140 so that the oil can flow into the reservoir 140. Also, the oil outlet pipe 160 is connected to the reservoir 140 so that the oil flows out of the reservoir 140. That is, the oil outflow pipe 160 is provided in the outflow hole 142 formed at the center of the reservoir 140 so that the oil can flow out from the inside of the reservoir 140.

Meanwhile, the flow meter 170 is installed in at least one of the oil inflow pipe 150 and the oil outflow pipe 160. For example, the flow meter 170 may include a first flow meter 172 installed in the oil inlet pipe 150 and a second flow meter 174 installed in the oil outlet pipe 160.

The first flow meter 172 and the second flow meter 174 are connected to the oil level controller 200. That is, the first flow meter 172 sends a signal to the oil level regulator 200 about the flow rate of the oil flowing into the reservoir 140 through the oil inlet pipe 150. The second flow meter 174 sends a signal to the oil level controller 200 about the flow rate of the oil flowing out of the reservoir 140 through the oil outlet pipe 160.

One end of the auxiliary outlet pipe 180 is connected to the drain hole 144 of the reservoir 140 and the other end is connected to the oil outlet pipe 160. On the other hand, the auxiliary outlet pipe 180 is connected to the oil outflow pipe 160 at the upstream side of the second flow meter 174 in the oil flow path.

The valve 190 is installed in the auxiliary outlet pipe 180 to control the flow rate of the water discharged through the auxiliary outlet pipe 180. The valve 190 is connected to the oil level regulator 200 to adjust the opening and closing degree of the auxiliary outlet pipe 180 according to the signal from the oil level regulator 200.

The oil level regulator 200 is connected to the first and second flow meters 172 and 174 and the valve 190 to open and close the valve 190 according to signals from the first and second flow meters 172 and 174, Adjust the opening degree.

That is, when the flow rate detected from the second flow meter 174 and the flow rate detected from the first flow meter 172 change abruptly, the flow rate flowing through the valve 190 can be controlled to prevent leakage, It is possible to adjust the low flow rate of the refrigerant.

As described above, the amount of stored oil can be adjusted while solving the oil leakage problem through the flow meter 170, the valve 190 and the oil level regulator 200.

Hereinafter, a rotating shaft cooling apparatus according to another embodiment of the present invention will be described with reference to the drawings. However, the same components as those described above are denoted by the same reference numerals, and a detailed description thereof will be omitted and the above description will be omitted.

2 is a schematic block diagram of a rotating shaft cooling apparatus according to another embodiment of the present invention.

2, the rotary shaft cooling apparatus 300 includes a rotary shaft 110, a bearing 120, an oil ring 130, a reservoir 340, an oil inlet pipe 150, an oil outlet pipe 160, A flow meter 170, a valve 390, and an oil level controller 400. The oil level controller 400 may include a controller (not shown).

The rotary shaft 110, the bearing 120, the oil ring 130, the oil inlet pipe 150, the oil outlet pipe 160, and the flow meter 170 have the same configurations as those described above, do.

The reservoir 340 serves to store the oil so that the lower end of the oil ring 130 is locked. The reservoir 340 may be fixed to the apparatus body (not shown), and a reservoir (not shown) may be formed in the reservoir 340 to receive the lower end of the rotation shaft 110.

Further, the reservoir 340 may have an inner space and may have an open top shape so as to store the oil.

The reservoir 340 may include an inlet hole (not shown) and an outlet hole 342 through which the oil inlet pipe 150 and the oil outlet pipe 160 are installed. The outlet hole 342 is formed to have the same height as the oil level stored in the preset reservoir 340.

That is, the outlet hole 142 is formed in the reservoir 340 so as to be disposed at the same position as the predetermined water level so as to prevent the oil level from becoming lower than a certain water level.

The valve 390 may include a first valve 392 installed in the oil inlet pipe 150 and a second valve 394 installed in the oil outlet pipe 160. The first valve 392 may be installed in the oil inflow pipe 150 so as to be disposed at the front end of the first flow meter 172 on the oil flow path. The second valve 394 may be installed in the oil outflow pipe 160 so as to be disposed at the rear end of the second flow meter 174 on the oil flow path.

The first and second valves 392 and 394 are connected to the oil level regulator 400 so that the oil level regulator 400 adjusts the opening and closing degree and opening degree of the oil level regulator 400 so as to regulate the measured flow rate from the first and second flow meters 172 and 174. [ .

The oil level regulator 400 is connected to the first and second flow meters 172 and 174 and the first and second valves 392 and 394 as described above and is connected to the first and second flow meters 172 and 174, 2 valves 392 and 394 are controlled.

That is, when the flow rate detected from the second flow meter 174 and the flow rate detected from the first flow meter 172 change abruptly, the flow rate flowing through the first and second valves 392 and 394 is adjusted to prevent leakage And the low flow rate of the reservoir 140 can be adjusted.

As described above, the amount of stored oil can be adjusted while solving the oil leakage problem through the flow meter 170, the valve 390, and the oil level regulator 400.

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, but, on the contrary, It will be obvious to those of ordinary skill in the art.

100: Rotary shaft cooling device
110:
120: Bearings
130: Oiling
140: Reservoir
150: Oil inflow pipe
160: Oil outflow pipe
170: Flowmeter
180: auxiliary outlet pipe
190: Valve
200: Oil level regulator

Claims (5)

A rotating shaft;
A bearing rotatably supporting the rotary shaft;
An oil ring inserted in the bearing and rotated in association with the rotation shaft;
A reservoir in which oil is stored such that a lower end of the oil ring is locked;
An oil inlet pipe connected to the reservoir to allow oil to flow into the reservoir;
An oil outflow pipe connected to the reverber to allow the oil to flow out from the reservoir;
A flow meter installed in at least one of the oil inlet pipe and the oil outlet pipe; And
A valve for controlling the amount of oil flowing in and out of the river bed;
And a rotating shaft.
The method according to claim 1,
Wherein the reservoir is formed with a drain hole through which the auxiliary outlet pipe is connected to the bottom surface, and the valve is installed in the auxiliary outlet pipe.
3. The method of claim 2,
Wherein the valve is connected to an oil level regulator for regulating opening and closing of the valve in accordance with flow rate information from the flow meter.
The method according to claim 1,
Wherein the valve includes a first valve installed in the oil inlet pipe and a second valve installed in the oil outlet pipe.
5. The method of claim 4,
Wherein the first valve and the second valve are connected to an oil level controller.

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