KR20190040780A - Cooling system for seawater pump, and seawater pump system having the same - Google Patents

Abstract

The present invention relates to a seawater pump, and more specifically, to a seawater pump cooling system to cool down the seawater pump. According to the present invention, the seawater pump cooling system is to cool down an electric motor (2a) of a seawater pump system (2) installed on a flow path (1) for supplying seawater. The electric motor (2a) comprises a motor housing (340) in which a stator and a rotor of the electric motor (2a) are installed. According to the present invention, the seawater pump cooling system comprises: a cooling module (100) including: an air flow formation unit (110) which absorbs external air and forms an air flow to make the absorbed external air flow into the motor housing (340); and a cooling unit (120) installed on an air flow path (P) formed by the air flow formation unit (100) to cool down the air flowing along the air flow path (P) by cooling water flowing therein; and a cooling water cooling unit (200) installed together with the cooling unit (120) to make the cooling water circulate, which cools down the cooling water received from the cooling unit (120) and transfers the cooling water to the cooling unit (120). According to the present invention, the seawater pump cooling system is able to guarantee a stable operation of the seawater pump.

Description

Technical Field [0001] The present invention relates to a seawater pump cooling system and a seawater pump system having the seawater pump cooling system,

The present invention relates to a seawater pump, and more particularly to a seawater pump cooling system for cooling a seawater pump.

A thermal power plant is a power plant that uses a steam boiler to turn a turbine and generate thermal power. The water past the turbine is used again after being cooled in the condenser. This is known as the Rankine cycle. Because it uses various fuels to make steam, this plant is characterized by many variants.

On the other hand, a lot of water is required for cooling the condenser and the like, and it is generally installed in the vicinity of the water-rich sea to use the sea water for cooling. 1, the seawater is supplied to a condenser or the like of a power plant using a seawater pump system 2 installed in a flow path 1 for supplying seawater.

Here, the flow path 1 and the seawater pump system 2 for supplying seawater are exposed to a change in temperature as they are normally installed outdoors as a large facility, and the seawater pump system 2 including the electric motor 2a is subjected to a meteorological change .

As a result, the temperature is very high as in the summer, and further, the electric motor 2a is heated by the direct sunlight to break the electric parts.

An object of the present invention is to provide a seawater pump cooling system capable of ensuring stable operation of a seawater pump by cooling an electric motor constituting a seawater pump to solve the above problems.

SUMMARY OF THE INVENTION The present invention has been made in order to achieve the above-mentioned object of the present invention, and it is an object of the present invention to provide a seawater pump system in which water for cooling an electric motor (2a) The pump cooling system according to claim 1, wherein the electric motor (2a) includes a motor housing (340) having a stator and a rotor of the electric motor (2a) therein and sucking outside air to flow into the motor housing The air flow forming unit 110 is provided on the air flow path P formed by the air flow forming unit 100. The cooling water flowing in the air flow forming unit 100 causes the air to flow along the air flow path P A cooling module (100) including a cooling part (120) for cooling the flowing air; And a cooling water cooling unit 200 installed to circulate cooling water together with the cooling unit 120 to cool the cooling water transferred from the cooling unit 120 and transfer the cooling water to the cooling unit 120 A seawater pump cooling system is disclosed.

The cooling module 100 may include a module housing 130 coupled to a side of the motor housing 340 when the rotary shaft 310 of the electric motor 2a is vertically oriented.

The module housing 130 may be directly coupled to the side wall of the motor housing 430 or may be coupled to the side wall of the motor housing 340 by a connection pipe 190 so that the air passage P is communicated .

The module housing 130 includes at least one first inlet 131 that is sucked externally by the air flow forming unit 110 and a second inlet 131 that is connected to the module housing 130 when the air flow forming unit 110 malfunctions. One or more second inlet ports 132 opened by the installed opening and closing part 180 to allow the outside air to be sucked into the module housing 130 are formed on the outer wall facing the surface coupled to the module housing 130 .

The present invention also includes a pumping section 2b installed in the flow path 1 for supplying seawater; A motor housing 340 coupled to a drive shaft of the pumping unit 2b to rotate the drive shaft and a motor 330 including a stator 330 and a rotor 320 installed inside the motor housing 340, A sea water pump (2) comprising; A seawater pump cooling system coupled to the motor housing 340 for sucking outside air and delivering the outside air to the motor housing 340 to cool the motor 2a, The present invention relates to a seawater pump system.

The cooling air supplied by the cooling module 100 flows through the stator 330 and the rotor 320 of the motor 2a and is discharged to the outside through one or more outlets (341) may be formed.

And a discharge hole 343 which is coupled to the discharge port 341 of the motor housing 340 and flows through the stator 320 and the rotor 330 of the electric motor 2a and then discharged downward when discharged to the outside, (350). ≪ / RTI >

The seawater pump cooling system and the seawater pump system having the seawater pump cooling system according to the present invention include a structure that is coupled to the motor housing to suck outside air and transfer it to the interior of the motor housing to cool the motor, There is an advantage that can be made.

Further, the seawater pump cooling system and the seawater pump system having the same according to the present invention may further include a cooling module for cooling the air and introducing the cooling air into the motor housing from the lower side of the motor housing provided inside the stator and the rotor It is possible to cool the motor, particularly the stator and the rotor, more efficiently, and to operate the seawater pump stably without overheating.

1 is a sectional view showing the concept of a sea water pump installed in a channel and a channel for supplying seawater.
2 is a conceptual diagram showing the concept of a seawater pump system including a seawater pump cooling system according to the present invention.
3 is a cross-sectional view showing a seawater pump and its associated cooling module in the seawater pump system of FIG. 2;
Fig. 4 is a plan view of the seawater pump system of Fig. 2 viewed from above. Fig.
5 is a cross-sectional view showing a configuration of a cooling module in the seawater pump system of FIG. 2;

Hereinafter, a seawater pump cooling system and a seawater pump system having the same according to the present invention will be described with reference to the accompanying drawings.

1 and 2, the seawater pump system according to the present invention comprises: a pumping portion 2b installed in the flow path 1 for supplying seawater; And a motor 2a including a motor housing 340 and a stator 330 and a rotor 320 installed inside the motor housing 340. The motor housing 340 is rotatably coupled to the driving shaft of the pumping unit 2b, A seawater pump (2) comprising; And a seawater pump cooling system that is coupled to the motor housing 340 to suck the outside air and deliver it to the inside of the motor housing 340 to cool the motor 2a.

The seawater pump 2 is installed in the channel 1 for supplying seawater and supplies seawater to a seawater supply source such as cooling water for power generation, and may have various configurations according to the configuration of the pumping system and the motor.

In particular, as shown in FIG. 1, the seawater pump 2 may be installed in various ways, such as being installed in the underground channel 1 in consideration of taking in seawater from the sea lower than the ground .

1 and 3, the seawater pump 2 includes: a pumping section 2b installed in the flow path 1 for supplying seawater; And a motor 2a including a motor housing 340 and a stator 330 and a rotor 320 installed inside the motor housing 340. The motor housing 340 is rotatably coupled to the driving shaft of the pumping unit 2b, .

The pumping unit 2b may have various configurations according to a pumping method installed in the flow path 1 for supplying seawater.

The electric motor 2a is coupled to a drive shaft of the pumping unit 2b to rotate the drive shaft and includes a motor housing 340, a stator 330 and a rotor 320 installed inside the motor housing 340 Various configurations are possible.

Particularly, the electric motor 2a has various internal structures according to a motorized system, and has a motor housing 340, a stator 342, The rotor 330 and the rotor 320 may have various configurations.

An auxiliary air flow forming part 311 such as a blade may be installed on the rotating shaft 310 or the rotor 320 to which the stator 330 is coupled so that air flows from the lower side to the upper side when the stator 330 rotates.

The auxiliary air flow forming part 311 is installed in the rotary shaft 310 or the rotor 320 to which the stator 330 is coupled and is configured to generate air flow from the lower side to the upper side when rotating, Do.

It is preferable that the motor housing 340 is provided with a stator 330 and a rotor 320 therein so that rainwater or the like is prevented from being introduced into the motor housing 340 considering that the motor housing 340 is installed outdoors.

The motor housing 340 may have various shapes such as a circular shape, an elliptical shape, and a polygonal shape when viewed from above.

The motor housing 340 can be manufactured by a variety of methods, such as a metal plate, a frame, or the like, which is manufactured by welding, assembling, or the like.

On the other hand, on the upper side of the motor housing 340, the cooling air supplied by the cooling module 100, which will be described later, flows through the stator 330 and the rotor 320 of the motor 2a, It is preferable that an outlet 341 is formed.

The outlet 341 is connected to the motor housing 340 so that the cooling air supplied by the cooling module 100 to be described later flows through the stator 330 and the rotor 320 of the motor 2a, An opening formed on the upper middle side, and may be formed variously according to a discharge mode.

In order to prevent the rainwater and the foreign matter from flowing into the inside by the formation of the discharge port 341 and smooth the air flow, the motor housing 340 is fixed to the stator 320 of the motor 2a, The discharge housing 350 may be further coupled to the discharge port 341 so as to form a discharge passage to be discharged downward when discharged through the electron 330.

The discharge housing 350 is connected to the discharge port 341 of the motor housing 340 so as to form a discharge flow path to be discharged downward when discharged through the stator 320 and the rotor 330 of the electric motor 2a, As shown in FIG.

For example, it is preferable that the discharge housing 350 has a shape corresponding to the shape of the edge of the discharge port 341 at one end and an exhaust port 351 at the other end located below the discharge port 341 .

The positions of the discharge port 341 and the discharge housing 350 are different from each other when the motor housing 340 is viewed from above with respect to the formation position of the first inlet 131 of the cooling module 100 Position.

Concretely, the air discharged through the discharge port 341 is heated while passing through the stator 320 and the rotor 330 of the electric motor 2a, and flows into the first inlet 131 of the cooling module 100 ) Is inadequate in terms of cooling efficiency of air.

The position of the discharge port 341 and the discharge housing 350 may be shifted relative to the position where the first inlet 131 of the cooling module 100 is formed when the motor housing 340 is viewed from above, The cooling efficiency can be greatly improved by minimizing the flow of the heated air heated inside the motor housing 340 into the first inlet 131 of the cooling module 100. [

The seawater pump cooling system may be variously configured as a structure for cooling the electric motor 2a by being coupled to the motor housing 340, sucking the external air and delivering it to the inside of the motor housing 340.

1 to 5, the seawater pump cooling system includes an air flow forming unit 110 for sucking outside air to form an air flow to flow into the motor housing 340, And a cooling unit 120 installed on the air passage P formed by the flow forming unit 100 and cooling the air flowing through the air passage P by the cooling water flowing in the cooling unit 120 100); And a cooling water cooling unit 200 installed to circulate the cooling water together with the cooling unit 120 to cool the cooling water transferred from the cooling unit 120 and transfer the cooling water to the cooling unit 120.

The cooling water cooling unit 200 may be configured to circulate the cooling water together with the cooling unit 120 so as to cool the cooling water transferred from the cooling unit 120 and transfer the cooling water to the cooling unit 120 .

For example, the cooling water cooling unit 200 can have various configurations according to the cooling method by cooling the cooling water.

For example, the cooling water cooling unit 200 may include a cooling channel through which heat can be exchanged, a cooling channel through which cooling water flows, and a cooling device through which cooling air flows through the cooling channel to cool cooling water flowing through the cooling channel.

The cooling channel may have various configurations according to a heat exchange system, and may include heat exchange fins coupled to a cooling pipe through which cooling water flows and a cooling pipe to increase heat exchange efficiency.

The cooling device can have various structures according to the cooling method, and can have various structures such as adopting a refrigeration cycle.

The cooling water cooling unit 200 includes a first cooling water channel 220 that receives cooling water from a cooling module 100 to be described later and a second cooling water channel 210 that transmits cooling water to the cooling module 100 after cooling, Lt; / RTI >

The first cooling water flow path 220 and the second cooling water flow path 210 are connected to the cooling water cooling unit 200 and the cooling module 100 so as to circulate the cooling water.

The first cooling water flow path 220 and the second cooling water flow path 210, in particular, the second cooling water flow path 210 through which the cooled cooling water flows, are insulated by a heat insulating member in order to prevent them from being heated by outside air desirable.

The heat insulating member is a member for inserting and insulating the second cooling water flow path 210, and may be composed of various members such as a thermally insulated by a tape method and a sponge having a hollow structure.

The cooling module 100 includes an air flow forming part 110 for sucking outside air and forming an air flow to flow into the motor housing 340 and an air flow path formed by the air flow forming part 100 P to cool the air flowing along the air flow path P by the cooling water flowing in the inside.

The cooling module 100 may include a module housing 130 coupled to a side of the motor housing 340 when the rotary shaft 310 of the electric motor 2a is vertically moved.

The module housing 130 is configured to be coupled to the side of the motor housing 340 when the rotary shaft 310 of the electric motor 2a is vertically arranged and is manufactured by various methods using a plate member, .

Particularly, the module housing 130 may have various shapes such as a rectangular parallelepiped for coupling with the side of the motor housing 340.

The module housing 130 may be directly coupled to the side wall of the motor housing 430 or may be coupled to the side wall of the motor housing 340 by the connection pipe 190 so that the air passage P is communicated.

The connection pipe 190 includes an outlet 138 formed in the module housing 130 to allow the air cooled in the module housing 130 to flow into the motor housing 430, And the pipe 345 are connected to each other.

Particularly, the connection pipe 190 may be formed of a braided tube or the like as a constitution for allowing the cooling air to flow into the motor housing 430, and the outer circumferential surface is preferably heat-treated by a heat insulating member such as tape or sponge.

In addition, the module housing 130 may have at least one first inlet 131 sucked externally by the air flow forming unit 110.

The first inlet 131 is formed in the module housing 130 and is sucked from the outside by the air flow forming part 110, and various configurations are possible.

In addition, the first inlet 131 preferably has a downwardly open structure to prevent water, foreign matter, and the like from entering the first inlet 131.

Meanwhile, when the air flow forming part 110 constituting the cooling module 100 is broken, the air flow is stopped and the inflow of air into the motor housing 340 is impeded, so that the cooling of the motor 2a is not smooth, May be a cause of failure such as overheating.

The module housing 130 is opened by the opening and closing part 180 installed in the module housing 130 in case of failure of the air flow forming part 110 so that the outside air is sucked into the module housing 130, 2 inlet 132 may be additionally formed.

The second inlet 132 is opened by an opening and closing unit 180 installed in the module housing 130 when the air flow forming unit 110 fails and sucks the outside air into the module housing 130 Structure.

The opening and closing part 180 may be configured such that the second inlet 132 is opened when the air flow part 110 is operated and the second inlet 132 is closed, So that the second inlet 132 is opened only in the event of a failure.

Meanwhile, the opening / closing unit 180 may include a shutter member rotated by a hinge shaft coupled to an upper end of the second inlet 132, (Not shown) that opens and closes the second inlet 132 by driving.

Meanwhile, the motor housing 340 is configured to be sucked into the module housing 130 when a separate air inlet is formed for the inflow of air into the motor housing 430 when the air flow forming unit 110 fails. It is needless to say that the opening and closing part 180 and the second inlet 132 opened and closed by the opening and closing part 180 are not necessarily required.

The driving unit rotates the shutter member to open or close the second inlet 132. Various configurations are possible according to the driving method.

The first inlet 131 and the second inlet 132 may be formed on the outer wall facing the surface coupled to the module housing 130 in consideration of cooling efficiency.

The air flow forming unit 110 may be configured to suck outside air to form an air flow so as to flow into the motor housing 340.

Specifically, the air flow forming part 110 may have various structures in consideration of an air flow forming method, a flow direction of a flow path, and the like.

The air flow forming part 110 may be formed at various positions such as inside and outside of the module housing 130 considering the air flow forming efficiency.

Further, the air flow forming part 110 may be located at least one of the front and rear of the air flow passage with respect to the position with respect to the cooling part 120.

The cooling unit 120 is provided on the air flow path P formed by the air flow forming unit 100 to cool the air flowing through the air flow path P by the cooling water flowing in the cooling unit 120 Various configurations are possible.

The cooling unit 120 includes a cooling water passage through which cooling water flows and a heat exchange fin (fin) coupled to the cooling passage to increase the cooling efficiency of the air flowing around the cooling passage. It is possible.

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 spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

Claims (7)

1. A seawater pump cooling system for cooling an electric motor (2a) of a seawater pump system (2) installed in a flow path (1) for seawater supply,
The electric motor 2a includes a motor housing 340 having a stator of the electric motor 2a and a rotor,
An air flow forming part 110 for sucking outside air and forming an air flow so as to flow into the motor housing 340 and an air flow path P formed by the air flow forming part 100 And a cooling unit (120) for cooling the air flowing through the air passage (P) by the cooling water flowing in the cooling unit (100);
And a cooling water cooling unit 200 installed to circulate cooling water together with the cooling unit 120 to cool the cooling water transferred from the cooling unit 120 and transfer the cooling water to the cooling unit 120 Seawater pump cooling system. The method according to claim 1,
Wherein the cooling module (100) comprises a module housing (130) coupled to a side of the motor housing (340) when the rotary shaft (310) of the motor (2a) system. The method of claim 2,
The module housing 130 is directly coupled to the side wall of the motor housing 430 or connected to the side wall of the motor housing 340 by the connection pipe 190 so that the air passage P is communicated A seawater pump cooling system. The method of claim 2,
The module housing (130)
At least one first inlet (131) sucked externally by the air flow forming part (110), and
At least one second inlet 132 is opened by the opening and closing part 180 installed in the module housing 130 to allow the outside air to be sucked into the module housing 130 when the air flow forming part 110 fails
Is formed on the outer side wall facing the surface coupled to the module housing (130). A pumping section (2b) installed in the flow path (1) for supplying seawater; A motor housing 340 coupled to a drive shaft of the pumping unit 2b to rotate the drive shaft and a motor 330 including a stator 330 and a rotor 320 installed inside the motor housing 340, A sea water pump (2) comprising;
The seawater pump cooling system according to any one of claims 1 to 4, which is coupled to the motor housing (340) and sucks external air to transfer the air into the motor housing (340) to cool the motor (2a) A seawater pump system including a seawater pump cooling system. The method of claim 5,
The cooling air supplied by the cooling module 100 flows through the stator 330 and the rotor 320 of the motor 2a and is discharged to the outside through one or more outlets (341). The method of claim 6,
And a discharge hole 343 which is coupled to the discharge port 341 of the motor housing 340 and flows through the stator 320 and the rotor 330 of the electric motor 2a and then discharged downward when discharged to the outside, (350). ≪ / RTI >

Images