KR102115788B1 - Cooling device for rotating shaft - Google Patents

Abstract

A rotating shaft, a bearing rotatably supporting the rotating shaft, an oil ring inserted into the bearing and rotated in cooperation with the rotating shaft, a reservoir in which oil is stored so that the lower end of the oil ring is locked, and connected to the reservoir An oil inlet pipe to be oiled into the reservoir, an oil outlet pipe connected to the reservoir to allow oil to flow out of the reservoir, a flow meter installed in at least one of the oil inlet pipe and the oil outlet pipe, and Disclosed is a rotary shaft cooling device including a valve that controls the amount of oil flowing in and out of a reservoir.

Description

Cooling device for rotating shaft

The present invention relates to a rotating shaft cooling device.

In general, the rotating device is provided with a rotating shaft and a bearing for fixing it. Then, oil is injected to reduce friction between the rotating shaft and the bearing and to cool.

The oil injected in this way flows into the reservoir under the bearing and circulates through a pipe connected to the reservoir.

On the other hand, the rotating device may operate at a temperature higher than the designed operating temperature due to manufacturing errors and differences in operating environments. In order to lower the temperature, more oil inflow is required, and when it exceeds a certain amount, it leads to a leakage problem.

In addition, even if the designed inflow amount is used, the oil level changes depending on the manufacturing error, the installed environment, and the viscosity of the oil to be used, leading to leakage problems.

Conventionally, a method of strengthening the function of the seal to prevent oil leakage, or to leave the oil to a certain degree, or to control the inflow of oil through an empirical method by an operator. However, in this way, it is difficult to find a non-leakage inflow and adjustment is required whenever the environment changes.

Therefore, there is a need to develop a structure that can solve the leakage problem and at the same time can be adjusted to the appropriate oil inflow.

Republic of Korea Patent Publication No. 2012-0003205

A rotating shaft cooling device capable of adjusting the storage amount of cooling oil is provided.

The rotating shaft cooling apparatus according to an embodiment of the present invention includes a rotating shaft, a bearing rotatably supporting the rotating shaft, an oil ring inserted into the bearing and rotated in conjunction with the rotating shaft, and a lower end of the oil ring locked A reservoir in which oil is stored, an oil inlet pipe connected to the reservoir to allow oil to flow into the reservoir, an oil outlet pipe connected to the reservoir to allow oil to flow out of the reservoir, the oil inlet pipe and the It includes a flow meter installed in at least one of the oil outflow pipe and a valve for adjusting the outflow and outflow of oil flowing in and out of the reservoir.

A drain hole in which the auxiliary outlet pipe is connected to the bottom surface is formed in the reservoir, and the valve may be installed in the auxiliary outlet pipe.

The valve may be connected to an oil level regulator that controls opening and closing of the valve according to flow 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 regulator.

There is an effect that can adjust the storage amount of the cooling oil.

1 is a schematic configuration diagram showing a rotating shaft cooling apparatus according to an embodiment of the present invention.
2 is a schematic configuration diagram showing 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, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for a more clear description.

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

Referring to Figure 1, the rotating shaft cooling apparatus 100 according to an embodiment of the present invention, as an example, the rotating shaft 110, the bearing 120, the oil ring 130, the reservoir 140, the oil inlet pipe 150 ), Oil outlet pipe 160, flow meter 170, auxiliary outlet pipe 180, valve 190 and may be configured to include an oil level regulator 200.

The rotating shaft 110 is rotatably installed on the device body (not shown) to serve to transmit rotational force.

Meanwhile, a bearing installation plate 112 for installing the bearing 120 may be formed on the rotation shaft 110. Furthermore, a seal forming member 102 may be installed at a rear end of the bearing installation plate 112 to form a lever seal for suppressing oil leakage.

The bearing 120 rotatably supports the rotating shaft 110. That is, the bearing 120 may have a substantially hollow cylindrical shape so that the rotating shaft 110 is installed through. In addition, a through hole 122 through which the oil ring 130 rotates in connection with the rotating shaft 110 may be formed in the bearing 120.

The oil ring 130 is installed to penetrate the through hole 122 of the bearing 120 and rotates in conjunction with the rotating shaft 110. Then, the oil ring 130 is disposed so that the lower end is immersed in the oil stored in the reservoir 140.

In this way, the oil ring 130 is rotated in conjunction with the rotating shaft 110, and at the same time, the lower end of the oil ring 130 is arranged to be immersed in oil, so the oil by the oil ring 130 causes the bearing 120 and the rotating shaft ( It is transferred to 110) to cool the heat due to friction between the bearing 120 and the rotating 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 fixedly installed in the device body (not shown), and an installation groove (not shown) in which the lower end of the rotating shaft 110 is inserted may be formed in the reservoir 140.

Furthermore, the reservoir 140 may have an internal space and an upper portion may be opened to store oil.

Meanwhile, an inflow hole (not shown) and an outflow hole 142 in which the above-described oil inflow pipe 150 and oil outflow pipe 160 are installed may be formed in the reservoir 140. In addition, the outlet hole 142 is formed to have the same height as the level of oil stored in the preset reservoir 140.

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

In addition, a drain hole 144 for installing the auxiliary outflow pipe 180 may be formed at the bottom of the reservoir 140.

The oil inlet pipe 150 is connected to the reservoir 140 to allow oil to flow into the reservoir 140. That is, the oil inlet pipe 150 is installed in the inlet hole formed in the upper end of the reservoir 140 so that oil can flow into the reservoir 140. In addition, the oil outlet pipe 160 is connected to the reservoir 140 to allow oil to flow out of the reservoir 140. That is, the oil outlet pipe 160 is installed in the outlet hole 142 formed on the central portion side of the reservoir 140 so that oil can be discharged from the interior of the reservoir 140.

On the other hand, the flow meter 170 is installed in at least one of the oil inlet pipe 150 and the oil outlet pipe 160. As an example, the flowmeter 170 may include a first flowmeter 172 installed in the oil inlet pipe 150 and a second flowmeter 174 installed in the oil outlet pipe 160.

In addition, the first flow meter 172 and the second flow meter 174 are connected to the oil level regulator 200. That is, the first flow meter 172 transmits a signal for the flow rate of oil flowing into the reservoir 140 through the oil inlet pipe 150 to the oil level regulator 200. Then, the second flow meter 174 transmits a signal for the flow rate of the oil flowing out of the reservoir 140 through the oil outlet pipe 160 to the oil level regulator 200.

The auxiliary outlet pipe 180 has one end connected to the drain hole 144 of the reservoir 140 and the other end connected to the oil outlet pipe 160. On the other hand, the auxiliary outlet pipe 180 is connected to the oil outlet pipe 160 at the front end of the second flow meter 174 on the flow path of the oil.

In addition, the valve 190 is installed in the auxiliary outlet pipe 180 and serves to control the flow rate flowing through the auxiliary outlet pipe 180. On the other hand, the valve 190 is connected to the oil level regulator 200 and controls 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 as described above, and opens and closes the valve 190 according to signals from the first and second flow meters 172 and 174. Adjust the degree of opening.

That is, when the flow rate detected from the second flowmeter 174 and the flow rate detected from the first flowmeter 172 change rapidly, the flow rate through the valve 190 can be adjusted to prevent leakage. The low flow rate of 140 can be adjusted.

As described above, it is possible to solve the leakage problem through the flow meter 170, the valve 190, and the oil level regulator 200, and at the same time, adjust the storage amount of the oil.

Hereinafter, a rotating shaft cooling apparatus according to another embodiment of the present invention will be described with reference to the drawings. However, for the same components as those described above, reference numerals used above will be omitted, and detailed descriptions will be omitted and replaced with the above-described descriptions.

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

Referring to Figure 2, the rotating shaft cooling device 300 is an example, the rotating shaft 110, the bearing 120, the oil ring 130, the reservoir 340, the oil inlet pipe 150, oil outlet pipe 160 , It may be configured to include a flow meter 170, the valve 390 and the oil level regulator 400.

The rotating 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 configuration as described above, and thus detailed description thereof will be omitted. 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 fixedly installed in the apparatus body (not shown), and an installation groove (not shown) in which the lower end of the rotating shaft 110 is inserted may be formed in the reservoir 340.

Furthermore, the reservoir 340 may have an internal space and an upper portion may be opened to store oil.

Meanwhile, an inlet hole (not shown) and an outlet hole 342 in which the above-described oil inlet pipe 150 and oil outlet pipe 160 are installed may be formed in the reservoir 340. Then, the outlet hole 342 is formed to have the same height as the level of oil stored in the preset reservoir 340.

That is, the outlet hole 142 is formed in the reservoir 340 to be disposed at the same position as the predetermined water level to prevent the oil level from being lowered below a certain 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 inlet pipe 150 to be disposed at the front end of the first flow meter 172 on the oil flow path. Then, the second valve 394 may be installed in the oil outlet pipe 160 to be disposed at the rear end of the second flow meter 174 on the oil flow path.

In addition, the first and second valves 392 and 394 are connected to the oil level regulator 400 so that the opening and closing degree is adjusted by the oil level regulator 400 to adjust the measured flow rate from the first and second flow meters 172 and 174. Can be.

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, according to the signals from the first and second flow meters 172 and 174. 2 Adjusts the degree of opening and closing of the valves 392 and 394.

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 rapidly, the flow rate through the first and second valves 392 and 394 is adjusted to prevent leakage. At the same time, the low flow rate of the reservoir 140 can be adjusted.

As described above, it is possible to solve the leakage problem through the flow meter 170, the valve 390, and the oil level regulator 400, and at the same time, adjust the storage amount of the oil.

Although the embodiments of the present invention have been described in detail above, the scope of rights of the present invention is not limited to this, and it is possible that various modifications and variations are possible without departing from the technical spirit of the present invention as set forth in the claims. It will be apparent to those of ordinary skill in the field.

100: rotating shaft cooling device
110: rotating shaft
120: bearing
130: oil ring
140: reservoir
150: oil inlet pipe
160: oil outlet pipe
170: flow meter
180: auxiliary outflow tube
190: valve
200: oil level regulator

Claims (5)

Axis of rotation;
A bearing rotatably supporting the rotating shaft;
An oil ring inserted into the bearing and rotated in cooperation with the rotating shaft;
A reservoir in which oil is stored so that the 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 reservoir to allow oil to flow out of the reservoir;
A flow meter installed on at least one of the oil inlet pipe and the oil outlet pipe; And
Includes a valve for adjusting the amount of oil flowing in and out of the reservoir;
In the reservoir, an outlet hole to which the oil outlet pipe is connected is formed,
The outlet hole is formed in the reservoir so as to have the same height as the water level of the oil stored in the reservoir, the rotary shaft cooling device, characterized in that to prevent the oil level from being lowered below a certain level.
According to claim 1,
A drain hole in which an auxiliary outflow pipe is connected to a bottom surface is formed in the reservoir, and the valve is a rotary shaft cooling device installed in the auxiliary outflow pipe.
According to claim 2,
The valve is a rotary shaft cooling device connected to an oil level regulator that controls opening and closing of the valve according to flow information from the flow meter.
According to claim 1,
The valve comprises a first valve installed in the oil inlet pipe, and a second shaft cooling device including a second valve installed in the oil outlet pipe.
The method of claim 4,
The first valve and the second valve are rotary shaft cooling devices connected to the oil level regulator.

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