JP2001012487A - Bearing cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bearing cooling device at a low cost and to surely supply cooling water by mounting a main pressure control valve capable of reducing the pressure of the cooling water, between a cooling water supply source and a shaft cooling pump. SOLUTION: A motor is driven and the cooling water is supplied to a supply line 10 by a cooling water supply pump 3. The cooling water flows into a main pressure control valve 14 after the foreign matter and the like mixed in the cooling water is removed by a strainer 12. The cooling water of high pressure pressurized by the cooling water supply pump 3 is depressurized to a predetermined value by the main pressure control valve 14. Whereby the pressure of a joint point 18 of the supply line 10 and a return line 8 is controlled to a desired value, and the cooling water of the suitable pressure flows to a suction port of a shaft cooling pump 5. Further as the residual part of the cooling water is discharged by a relief valve 17, the cooling water of suitable pressure flows into the shaft cooling pump 5 even when the pressure of the cooling water between the main pressure control valve 14 and the shaft cooling pump 5 is over the desired pressure.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a bearing cooling device, and more particularly to a bearing cooling device suitable for cooling bearings of a main turbine, a generator, a pump, and the like included in a power plant or the like.

[0002]

2. Description of the Related Art In power plants such as thermal and nuclear power plants, bearing cooling devices for main turbines and generators, bearing cooling devices for various pumps, and other devices requiring cooling water (hereinafter referred to as "cooling target devices"). A bearing cooling device for supplying cooling water thereto is provided. FIG. 5 shows a conventional bearing cooling device. The bearing cooling device 100 shown in FIG.
The supply unit 103 includes a cooling water supply pump 102 serving as a supply source of the cooling water supplied to the cooling water supply unit 01, and the cooling water is supplied between the shaft cooling pump 104 and the cooling target device 101 so as to minimize the consumption of the cooling water. And a circulating unit 105 that circulates the water. The circulation unit 105 is a supply side 106 that supplies the cooling water discharged from the shaft cooling pump 104 to the cooling target device 101.
And a return side 108 including a return line 107 for allowing the cooling water that has cooled the cooling target device 101 to flow back into the shaft cooling pump 104.

A supply line 109 is connected to a discharge port of a cooling water supply pump 102 included in the supply section 103, and a tank 110 for storing cooling water such as pure water is connected to a suction port. I have. A stop valve 111 is provided in the supply line 109, and a strainer 112 for removing contaminants and the like from the cooling water in the supply line 109 is provided downstream of the stop valve 111. Further, a pressure regulating valve 113 is provided downstream of the strainer 112. A bypass line 114 is branched from the supply line 109, and a bypass valve 115 that can be manually opened and closed is provided in the bypass line 114.

[0004] The bypass line 114 is connected to the pressure regulating valve 11.
At the downstream of 3 and joins the supply line 109,
A shaft cooling head tank (stand pipe) 116 is provided downstream of the junction. A controller 117 is provided for the shaft cooling head tank 116. The controller 117 measures the pressure at the junction 119 between the supply line 109 and the return line 107 included in the return side 108 and the liquid level (water level) of the axial cooling head tank 116, and outputs a control signal via a signal line 118. Pressure regulating valve 1
13 to change the opening of the pressure regulating valve 113.

[0005] Downstream of the junction 119, the shaft cooling pump 1
04 is provided. A supply line 120 is connected to a discharge port of the shaft cooling pump 104, and the supply line 120 is provided with a cooler 121. Furthermore,
A control valve 122 is provided downstream of the cooler 121. Further, a supply bypass line 123 is branched from the supply line 120.
23 is provided with a control valve 124. The supply bypass line 123 joins the supply line 120 downstream of the control valve 124, and a temperature controller 125 connected to the control valves 122 and 124 is provided downstream of the junction. The opening degrees of the control valves 122 and 124 change according to an electric signal from the temperature controller 125.

[0006] The cooling water whose temperature is controlled by the control valves 122 and 124 and the temperature controller 125 flows into various cooling target devices 101. The cooling water that has cooled the cooling target device 101 flows into the suction port of the shaft cooling pump 104 via the return line 107 and the junction 119. In addition,
The surplus cooling water is discharged from a discharge line 126 to a tank (not shown) or the like.

In this bearing cooling device 100, the pressure of the cooling water supplied to the shaft cooling pump 104 is adjusted by changing the opening of the pressure adjusting valve 113 and the shaft cooling head tank 116.
This is done by adjusting the water level. That is, in the bearing cooling device 100, the pressure of the cooling water (for example, 16 kg / cm ² ) discharged from the cooling water supply pump 102 is adjusted by a pressure adjusting valve so as to maintain the water level of the shaft cooling head tank 116 at a predetermined height. By changing the opening of 113, a predetermined value (for example, 4 kg / cm ² ) is set.

[0008]

However, the above-described bearing cooling device 100 has the following problems.
That is, in the conventional bearing cooling device 100, by adjusting the water level of the shaft cooling head tank 116, the shaft cooling pump 10
The pressure of the cooling water flowing into 4 was adjusted. For this reason,
Depending on the required pressure of the cooling water, a shaft cooling head tank 116 having a considerable height is required, which increases the manufacturing cost of the bearing cooling device 100 and restricts the installation of the shaft cooling head tank 116. There was a problem.

Further, in the conventional bearing cooling device 100, the shaft cooling head tank 116 is directly connected to the shaft cooling pump 104 for supplying cooling water to the various devices 101 to be cooled. When the operation stops, the cooling water is not supplied to the cooling target device 101 which needs cooling, or the various cooling target devices 10
There was also a risk that cooling of No. 1 could not be performed at all.
Further, when the shaft cooling head tank 116 is deteriorated and rust is generated, cooling water mixed with rust is supplied to the cooling target device 101, and the performance of the shaft cooling pump 104, the cooling target device 101, and the like is reduced. There was also the possibility of adverse effects.

The present invention has been made based on the above technical background, and has as its object to provide a bearing cooling device which can be configured at low cost and can reliably supply cooling water. .

[0011]

According to a first aspect of the present invention, there is provided a bearing cooling device for supplying cooling water from a cooling water supply source to a shaft cooling pump, and supplying the cooling water between the shaft cooling pump and a device to be cooled. In the bearing cooling device, the main pressure control valve for reducing the pressure of the cooling water is provided between the cooling water supply source and the shaft cooling pump.

According to the first aspect of the present invention, when supplying the cooling water from the cooling water supply source to the shaft cooling pump, the cooling water is provided between the cooling water supply source and the shaft cooling pump. The pressure is appropriately reduced by the main pressure control valve and then flows into the shaft cooling pump. This eliminates the need for the conventionally used shaft cooling head tank, thereby reducing the manufacturing cost of the bearing cooling device and, at the same time, causing trouble due to the failure or deterioration of the shaft cooling head tank, that is, cooling water to the cooling target device. Can be eliminated, and troubles such as rust mixing in the cooling water can be solved. In addition, it is possible to easily arrange the piping between the cooling water supply source and the shaft cooling pump.

The bearing cooling device according to the present invention is characterized in that an auxiliary pressure control valve for reducing the pressure of the cooling water is provided between the main pressure control valve and the cooling water supply source. I do.

According to the bearing cooling device of the present invention, since the cooling water is depressurized by the auxiliary pressure control valve before the cooling water flows into the main pressure control valve, the burden on the main pressure control valve can be reduced. Meanwhile, cooling water at an appropriate pressure can be supplied to the shaft cooling pump.

The bearing cooling device according to the present invention is characterized in that a relief valve for discharging excess cooling water is provided between the main pressure control valve and the shaft cooling pump.

According to the third aspect of the present invention, even if the pressure of the cooling water between the main pressure control valve and the shaft cooling pump is higher than necessary, the excess amount of the cooling water from the relief valve can be obtained. Is discharged, so that cooling water at an appropriate pressure can be supplied to the shaft cooling pump.

According to a fourth aspect of the present invention, in the bearing cooling device, the main pressure control valve is a self-powered self-regulating valve.

According to a fifth aspect of the present invention, in the bearing cooling device, the main pressure control valve is a self-acting automatic control valve, the pressure of the cooling water is detected downstream of the main pressure control valve, and based on the detected value. And a pressure controller for controlling the opening of the main pressure control valve is provided.

In the bearing cooling device according to the present invention, a branch pipe for supplying cooling water to another system is provided between the main pressure control valve and the shaft cooling pump. A control valve is provided.

According to the bearing cooling device of the sixth aspect, it is possible to supply surplus cooling water to another system through the branch pipe after controlling the pressure by the pressure control valve.
Cooling water can be used effectively.

The bearing cooling device according to the present invention is characterized in that an air vent for removing gas contained in the cooling water is provided downstream of the main pressure control valve.

According to the seventh aspect of the present invention, when gas is mixed in the cooling water supplied from the cooling water supply source, the gas in the cooling water is discharged from the air vent. This makes it possible to supply cooling water having an appropriate pressure to the shaft cooling pump.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a bearing cooling device according to the present invention will be described with reference to the drawings. FIG.
1 is a system diagram showing a first embodiment of a bearing cooling device according to the present invention. The bearing cooling device 1 shown in FIG. 1 supplies cooling water to various cooling target devices 2 that require bearing cooling. The bearing cooling device 1 serves as a supply source of cooling water supplied to the cooling target device 2 and includes a replenishing unit 4 including a cooling water supply pump 3 driven by a motor (not shown).
And a circulating unit 6 for circulating the cooling water between the shaft cooling pump 5 and the cooling target device 2 so as to minimize the consumption of the cooling water. The circulating unit 6 includes a supply side 7 that supplies cooling water discharged from the shaft cooling pump 5 to the cooling target device 2,
And a return side 9 including a return line 8 for allowing the cooling water that has cooled the cooling target device 2 to flow into the shaft cooling pump 5 again.

A supply line 10 is connected to a discharge port of the cooling water supply pump 3 included in the supply section 4, and a tank 11 for storing cooling water such as pure water is connected to a suction port. I have. The supply line 10 is provided with a strainer 12 for removing contaminants and the like from the cooling water, and a stop valve 13 is provided downstream of the strainer 12. A main pressure control valve 14 is provided downstream of the stop valve 13.

The main pressure control valve 14 has a control pipe 14a connected downstream of the main pressure control valve 14 to the supply line 10. The main pressure control valve 14 automatically adjusts the opening of the valve port using the pressure of the cooling water. A valve for reducing the pressure of the high-pressure (for example, 16 kg / cm ² ) cooling water to a predetermined value (for example, 4 kg / cm ² ). in this way,
In the bearing cooling device 1, since the cooling water is depressurized by the main pressure control valve 14, the shaft cooling pump 5
The cooling water at an appropriate pressure can be supplied to the cooling water.

A bypass line 15 is branched from the supply line 10 between the strainer 12 and the stop valve 13, and the bypass line 15 is provided with a bypass valve 16 which can be opened and closed manually. Bypass line 15
The supply line 10 is located downstream of the main pressure control valve 14.
Has joined. When the pressure of the cooling water in the supply line 10 exceeds a predetermined value, a valve port is automatically opened downstream of the junction of the supply line 10 and the bypass line 15 so that the surplus cooling water is stored in a tank or the like. Release valve 1
7 are provided.

The supply line 10 joins the return line 8 downstream of the relief valve 17, and the shaft cooling pump 5 is provided downstream of the junction 18. Cooling water reduced to a predetermined value by the main pressure control valve 14 flows into the suction port of the shaft cooling pump 5. The cooling water pressurized by the shaft cooling pump 5 and discharged from the discharge port of the shaft cooling pump 5 is as follows:
Circulates between the shaft cooling pump 5 and the equipment 2 to be cooled.

A supply line 19 is connected to a discharge port of the shaft cooling pump 5 included in the circulating section 6, and the supply line 19 is provided with a cooler 20. Further, a control valve 21 is provided downstream of the cooler 20. From between the shaft cooling pump 5 and the cooler 20 of the supply line 19,
The supply bypass line 22 is branched, and a control valve 23 is provided in the supply bypass line 22.
The supply bypass line 22 joins the supply line 19 downstream of the control valve 23, and a temperature controller 24 connected to the control valves 21 and 23 is provided downstream of the junction. The degree of opening of the control valves 21 and 23 changes according to an electric signal from the temperature controller 24.

Control valves 21 and 23 and temperature controller 2
The cooling water whose temperature is controlled by the cooling device 4
Supplied to The cooling target device 2 is cooled by the cooling water having the appropriate pressure and temperature. Equipment to be cooled 2
The cooling water that has been cooled is returned to the return line 8 included in the return side 9.
Flows into the confluence 18 via the flow path, and flows into the suction port of the shaft cooling pump 5. The surplus cooling water is discharged from the discharge line 25 to a tank (not shown) or the like.

Next, the operation of the bearing cooling device 1 will be described. First, a prime mover (not shown) is driven, and cooling water is supplied to the supply line 10 by the cooling water supply pump 3.
After the contaminants and the like are removed by the strainer 12, the cooling water flows into the main pressure control valve 14. The high-pressure cooling water pressurized by the cooling water supply pump 3 is supplied to the main pressure control valve 1.
4, the pressure is reduced to a predetermined value. As a result, the pressure at the junction 18 between the supply line 10 and the return line 8 becomes a desired value, and cooling water having an appropriate pressure flows into the suction port of the shaft cooling pump 5. Further, even in a case where the pressure of the cooling water between the main pressure control valve 14 and the shaft cooling pump 5 becomes equal to or higher than a desired pressure, the excess amount of the cooling water is discharged by the relief valve 17. Cooling water having an appropriate pressure flows into the shaft cooling pump 5.

The cooling water that has flowed into the suction port of the shaft cooling pump 5 is pressurized by the shaft cooling pump 5 and controlled by control valves 21 and 23.
And the temperature controller 24 controls the temperature. Thereby, the cooling water having an appropriate pressure and temperature is supplied to the cooling target device 2. The cooling water flowing out of the cooling target device 2 flows into the return line 8, and flows again into the shaft cooling pump 5 via the junction 18. The surplus cooling water in the circulation section 6 is discharged from a discharge line 25 to a tank (not shown) or the like.

As described above, according to the present embodiment, the main pressure control valve 14 is provided between the cooling water supply pump 3 and the shaft cooling pump 5.
By disposing the shaft cooling head tank conventionally used, the bearing cooling device 1 can be configured at low cost, and the cooling water at an appropriate pressure can be supplied to the shaft cooling pump 5.

Further, it is possible to solve a trouble caused by a failure or deterioration of the shaft cooling head tank, that is, a trouble that the cooling water cannot be supplied to the cooling target device 2 or rust is mixed in the cooling water. .

Furthermore, since the relief valve 17 is provided between the main pressure control valve 14 and the shaft cooling pump 5, the pressure of the cooling water between the main pressure control valve 14 and the shaft cooling pump 5 is reduced. Even if it is higher than necessary, the excess amount of the cooling water is discharged from the relief valve 17, and the cooling water at an appropriate pressure can be supplied to the shaft cooling pump 5.

Next, a second embodiment of the present invention will be described with reference to the drawings. The same members as those in the first embodiment are denoted by the same reference numerals, and redundant description will be omitted. In the present embodiment, a self-powered self-regulating valve is used as the main pressure control valve instead of the self-powered self-regulating valve.

The main pressure control valve 26, which is a self-regulating valve of other power type.
Is connected to a pressure controller 27 that detects the pressure of the cooling water in the supply line 10 downstream of the main pressure control valve 26 and performs an arithmetic process based on the detected value. The pressure controller 27 gives a command signal to the main pressure control valve 26 based on the detected pressure value so that the pressure of the cooling water downstream of the main pressure control valve 26 becomes a predetermined value. In this manner, the cooling water in the supply line 10 downstream of the main pressure control valve 26 can be reduced by the main pressure control valve 26 which is a self-adjusting valve, and is included in the circulation unit 6. Cooling water having an appropriate pressure can flow into the shaft cooling pump 5.

With the bearing cooling device according to the second embodiment configured as described above, cooling water having an appropriate pressure can be supplied to the shaft cooling pump 5.

Next, a third embodiment of the present invention will be described with reference to the drawings. The same members as those in the first embodiment are denoted by the same reference numerals, and redundant description will be omitted. This embodiment is a bearing cooling device 1 according to the first embodiment.
In contrast, an auxiliary pressure control valve 29 is provided between the cooling water supply pump 3 and the main pressure control valve 14, and an air vent 30 is provided downstream of the main pressure control valve 14.

That is, as shown in FIG. 3, an auxiliary pressure control valve 2 is provided between the cooling water supply pump 3 and the main pressure control valve 14.
9 are provided. The auxiliary pressure control valve 29 reduces the pressure of the cooling water in the supply line 10 before the cooling water flows into the main pressure control valve 14. That is, the cooling water is depressurized not only by the main pressure control valve 14 but also by the auxiliary pressure control valve 29.

The supply line 10 and the bypass line 1
An air vent 30 for discharging gas mixed in the cooling water of the replenishment line 10 to the outside of the system is provided on the downstream side of the junction with the air supply 30.
Is provided. Therefore, when gas is mixed in the cooling water of the supply line 10, the gas in the cooling water is discharged from the air vent 30.

According to the bearing cooling device according to the third embodiment configured as described above, the cooling water of an appropriate pressure can flow into the shaft cooling pump 5 while reducing the load on the main pressure control valve 14. Further, even if gas is mixed in the cooling water of the replenishment line 10, the gas in the cooling water is discharged from the air vent, so that the cooling water having an appropriate pressure can flow into the shaft cooling pump 5.

Next, a fourth embodiment of the present invention will be described with reference to the drawings. The same members as those in the first and second embodiments are denoted by the same reference numerals, and redundant description will be omitted. In the present embodiment, the main pressure control valve 14 which is a self-powered automatic control valve in the first embodiment is changed to a main pressure control valve 26 which is a self-powered automatic control valve, and the main pressure control valve 26 is Supply line 1 between pump 5
Branch line 33 for supplying 0 cooling water to another system
And a pressure control valve 32 is connected to the branch line 33.
It is provided with.

The main pressure control valve 26 and the pressure control valve 3
2 is controlled by the pressure controller 31. That is, as shown in FIG.
Detects the pressure of the cooling water in the supply line 10 downstream of the main pressure control valve 26 and, based on the detected value, feeds the cooling water of an appropriate pressure into the shaft cooling pump 5. In addition to controlling the opening of the main pressure control valve 26 via 28, the opening of the pressure control valve 32 is controlled via a signal line 34 in order to flow cooling water of an appropriate pressure into another system.

According to the bearing cooling device according to the fourth embodiment, the surplus cooling water in the replenishment line 10 is pressure-controlled by the pressure control valve 32, and is controlled via the branch line 33. Since it is possible to supply the cooling water to another system, the cooling water can be effectively used.

Although the bearing cooling device according to the present invention has been described in detail based on the embodiments, the present invention is not limited to the above embodiments. For example, in the first to fourth embodiments, the relief valve and the air vent may be replaced,
The main pressure control valve, the auxiliary pressure control valve and the pressure control valve may be changed from a self-powered self-regulating valve to a self-powered self-regulating valve or vice versa. Is also good.

[0046]

Since the present invention is configured as described above, the following effects can be obtained. That is, when supplying the cooling water from the cooling water supply source to the shaft cooling pump, the cooling water is:
The pressure is appropriately reduced by a main pressure control valve provided between the cooling water supply source and the shaft cooling pump, and is caused to flow into the shaft cooling pump. As a result, the cooling water is reliably supplied to the equipment to be cooled, and the conventionally used shaft cooling head tank becomes unnecessary, so that the manufacturing cost of the bearing cooling device can be reduced, and the failure of the shaft cooling head tank, It is possible to solve the trouble caused by the deterioration, that is, the trouble that the cooling water cannot be supplied to the cooling target device or the rust is mixed in the cooling water.

[Brief description of the drawings]

FIG. 1 is a system diagram showing a first embodiment of a bearing cooling device according to the present invention.

FIG. 2 is a system diagram showing a second embodiment of the bearing cooling device according to the present invention.

FIG. 3 is a system diagram showing a third embodiment of the bearing cooling device according to the present invention.

FIG. 4 is a system diagram showing a fourth embodiment of the bearing cooling device according to the present invention.

FIG. 5 is a system diagram of a conventional bearing cooling device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Bearing cooling device, 2 ... Equipment to be cooled, 3 ... Cooling water supply pump, 4 ... Supply part, 5 ... Shaft cooling pump, 6 ... Circulation part,
7 supply side, 8 return line, 9 return side, 10 supply line, 11 tank, 12 strainer, 14,
26: main pressure control valve, 17: relief valve, 18: confluence point, 2
0: cooler, 21, 23 ... control valve, 24: temperature controller, 27, 31 ... pressure controller, 28, 34 ... signal line, 29 ... auxiliary pressure control valve, 30 ... air vent, 32 ... pressure control valve, 33 ... Branch line.

Claims (7)

[Claims] 1. A bearing cooling device that supplies cooling water from a cooling water supply source to a shaft cooling pump and circulates the cooling water between the shaft cooling pump and a device to be cooled. A bearing cooling device, wherein a main pressure control valve for reducing the pressure of the cooling water is provided between the shaft cooling pump and the shaft cooling pump. 2. The bearing according to claim 1, wherein an auxiliary pressure control valve for reducing the pressure of the cooling water is provided between the main pressure control valve and the cooling water supply source. Cooling system. 3. The bearing according to claim 1, wherein a relief valve for discharging excess cooling water is provided between the main pressure control valve and the shaft cooling pump. Cooling system. 4. The bearing cooling device according to claim 1, wherein the main pressure control valve is a self-powered automatic regulating valve. 5. The main pressure control valve is a multi-force automatic control valve, detects the pressure of the cooling water downstream of the main pressure control valve, and controls the main pressure control valve based on a detected value. The bearing cooling device according to any one of claims 1 to 3, further comprising a pressure controller that controls an opening degree. 6. A branch pipe for supplying the cooling water to another system is provided between the main pressure control valve and the shaft cooling pump, and the branch pipe is provided with a pressure control valve. The bearing cooling device according to any one of claims 1 to 5, characterized in that: 7. An air vent according to claim 1, wherein an air vent for removing gas contained in said cooling water is provided downstream of said main pressure control valve. Bearing cooling device.