KR102141489B1 - Cooling tower and controlling method thereof - Google Patents

Abstract

The present invention relates to a cooling tower and its control method. An aspect of the cooling tower according to an embodiment of the present invention, the primary intake port through which the air heat-exchanged with the cooling water is sucked, the secondary intake port through which the air in which the heat exchanged with the cooling water is mixed is sucked through the main intake port, and heat exchanged with the cooling water A casing through which an exhaust port through which air or air mixed with air sucked through the auxiliary intake port is discharged is formed; A water supply unit supplying cooling water that is heat-exchanged with the air sucked through the main intake port; It is sucked into the inside of the casing through the main intake port and discharged to the outside of the casing through the exhaust port to form a flow of air that is heat-exchanged with cooling water, applied to a blower motor that rotates the blower fan and the blower motor Blower unit including an inverter for controlling the frequency of the power supply; A filling material in which heat exchanged between the air drawn into the casing through the main intake port and the cooling water supplied from the water supply unit; A collecting part through which cooling water exchanged with air in the filling material is collected; A damper that selectively opens and closes the auxiliary intake port; A temperature sensor for sensing the outlet temperature of the cooling water discharged from the water collecting unit to the outside; And a control unit for controlling the operation, wherein the control unit is discharged to the outside of the casing through a cooling priority mode or the exhaust port for controlling the inverter according to the outlet temperature of the coolant sensed by the temperature sensor. Operation is controlled in a white smoke prevention mode that controls the inverter and the damper according to whether white smoke is generated by air and the outlet temperature of the coolant sensed by the temperature sensor.

Description

Cooling tower and its control method{COOLING TOWER AND CONTROLLING METHOD THEREOF}

The present invention relates to a cooling tower and its control method.

In the cooling tower, the cooling tower serves to cool the air conditioning apparatus or a refrigerator, that is, cooling water used for condensation of refrigerant flowing through the refrigeration cycle by contacting with air. Such a cooling tower allows the cooling water to be sprayed into the air to exchange high-temperature cooling water, or the flowing cooling water to contact the blown air. Therefore, the cooling efficiency of the cooling water can be controlled substantially according to the amount of air sucked into the cooling tower.

On the other hand, in the winter season, when the temperature is relatively low, the relative humidity is increased by contact with the cooling water, and the air reaching the saturation humidity is discharged to the outside of the cooling tower and condensed with moisture contained in contact with low temperature outside air. ) Phenomenon occurs. In order to prevent such a phenomenon of white smoke, various technologies have been applied. For example, the air exchanged with the cooling water is pre-mixed with the outside air sucked into the inside of the cooling tower and then discharged to the outside of the cooling tower to prevent the white smoke phenomenon. Can.

Prior art document 1 (Republic of Korea Patent No. 0863771, name: cooling tower control method using active control) and prior art document 2 (Republic of Korea Patent No. 1250560, name: cooling tower control method) have a conventional cooling tower control method This is disclosed.

First, in the prior art document 1, the coolant outlet temperature is compared with the outdoor wet bulb temperature to control the rotation speed of the blower. And, in the prior art document 2, when the blowing fan is initially driven at the maximum rotational speed and the outlet temperature of the cooling water is lowered to a set value, and no white smoke occurs, the power consumption of the cooling water pump and the blowing fan is summed to minimize consumption power. It controls the rotational speed of the blower fan so as to be, and when white smoke is generated, the blowing fan is driven at the maximum rotational speed to control the outside air to be sucked into the cooling tower to mix with the coolant and the heat-exchanged air for the generation of white smoke. . However, in the case of the prior art document 1, there is a disadvantage that the reduction of the white smoke phenomenon cannot be more actively performed, and in the case of the prior art document 2, the blowing fan is driven at the maximum rotational speed regardless of the degree of the white smoke phenomenon, There is a disadvantage in that unnecessary power consumption is achieved or supercooling of the cooling water may occur.

Republic of Korea Patent No. 0863771 (Name: Cooling tower control method using active control) Republic of Korea Registered Patent No. 1250560 (name: cooling tower control method)

The present invention is to solve the problems by the prior art as described above, the object of the present invention is to provide a cooling tower and a control method thereof configured to be able to more effectively cool and prevent white smoke.

An aspect of the cooling tower according to an embodiment of the present invention for achieving the above object is a primary intake port through which the air heat-exchanged with the cooling water is sucked, an auxiliary intake port through which the air mixed with the cooling water and heat-exchanged air is sucked, and the main intake port A casing through which an exhaust port through which air sucked through and heat-exchanged with cooling water or air mixed with air sucked through the auxiliary intake port is discharged is formed; A water supply unit supplying cooling water that is heat-exchanged with the air sucked through the main intake port; It is sucked into the inside of the casing through the main intake port and discharged to the outside of the casing through the exhaust port to form a flow of air that is heat-exchanged with cooling water, applied to a blower motor that rotates the blower fan and the blower motor Blower unit including an inverter for controlling the frequency of the power supply; A filling material in which heat exchanged between the air drawn into the casing through the main intake port and the cooling water supplied from the water supply unit; A collecting part through which cooling water exchanged with air in the filling material is collected; A damper that selectively opens and closes the auxiliary intake port; A temperature sensor for sensing the outlet temperature of the cooling water discharged from the water collecting unit to the outside; And a control unit for controlling its operation, wherein the control unit is discharged to the outside of the casing through a cooling priority mode or the exhaust port for controlling the inverter according to the outlet temperature of the coolant sensed by the temperature sensor. Operation is controlled in a white smoke prevention mode that controls the inverter and the damper according to whether white smoke is generated by air and the outlet temperature of the coolant sensed by the temperature sensor.

In one aspect of the embodiment of the present invention, the control unit, in the cooling priority mode, the power applied to the blower motor until the outlet temperature of the cooling water sensed by the temperature sensor decreases below a preset first reference temperature When the inverter is controlled so that the frequency of is gradually increased from the initial frequency, and the outlet temperature of the coolant sensed by the temperature sensor decreases below the first reference temperature, power of the frequency at that time is supplied to the blower motor. It controls the inverter to be applied to.

In one aspect of the embodiment of the present invention, in the cooling priority mode, the control unit controls the inverter so that the frequency of the power applied to the blowing motor is increased in a range not exceeding a predetermined maximum frequency.

An aspect of the embodiment of the present invention further includes a vision camera for photographing an image of white smoke generated by air discharged to the outside of the casing through the exhaust port, and the control unit is an image captured by the vision camera Only when the height of the white smoke is determined to be higher than the preset height, the operation is controlled by the white smoke prevention mode.

In one aspect of the embodiment of the present invention, the control unit determines the degree of occurrence of white smoke in proportion to the height of white smoke in the image photographed by the vision camera in the white smoke prevention mode, and the opening degree is proportional to the occurrence of white smoke. The damper is controlled so that it increases.

In one aspect of the embodiment of the present invention, the control unit, in the anti-fogging mode, when the damper is open, when the outlet temperature of the coolant detected by the temperature sensor is lowered below a preset first reference temperature The inverter is controlled so that the frequency of the power applied to the blowing motor increases until the outlet temperature of the cooling water sensed by the temperature sensing sensor before the frequency of the power applied to the blowing motor reaches a preset maximum frequency. When the temperature falls below the first reference temperature, the inverter is controlled so that the power of the frequency at that time is applied to the blowing motor, and the temperature is applied even if the frequency of the power applied to the blowing motor reaches a preset maximum frequency. When the outlet temperature of the coolant sensed by the detection sensor exceeds the first reference temperature, the damper is opened so that the opening degree decreases until the temperature of the coolant sensed by the temperature sensor decreases below the first reference temperature. To control.

From the aspect of the embodiment of the invention one, wherein, in the white smoke prevention mode, the outlet temperature of the cooling water detected by the temperature sensor falls below the first reference temperature in the course of opening of the dampers reduces, The damper is controlled to maintain the opening degree at that point,

In one aspect of the embodiment of the present invention, the control unit, in the anti-fogging mode, the outlet temperature of the coolant detected by the temperature sensor in the state that the opening degree of the damper is maintained is set to less than the first reference temperature When the temperature falls below 2 reference temperature, the inverter is controlled so that the frequency of the power applied to the blower motor is reduced or the damper is controlled so that the opening degree is increased.

In one aspect of the embodiment of the present invention, in the case where the control unit, in the anti-fogging mode, the outlet temperature of the coolant detected by the temperature sensor is lowered below the second reference temperature in a state where the opening degree of the damper is maintained. In, when the height of the white smoke in the image photographed by the vision camera is reduced or maintained, the outlet temperature of the coolant detected by the temperature sensor increases above the second reference temperature and below the first reference temperature. The inverter is controlled so that the frequency of the power applied to the blower motor is reduced, and the damper is controlled to maintain the opening degree.

In one aspect of the embodiment of the present invention, in the case where the control unit, in the anti-fogging mode, the outlet temperature of the coolant detected by the temperature sensor is lowered below the second reference temperature in a state where the opening degree of the damper is maintained. In, when the height of white smoke in the image photographed by the vision camera is increased, until the outlet temperature of the coolant detected by the temperature sensor increases above the second reference temperature and below the first reference temperature The inverter is controlled to maintain the frequency of the power applied to the blower motor, and the damper is controlled to increase the opening degree.

An aspect of a method for controlling a cooling tower according to an embodiment of the present invention is a method for controlling a cooling tower according to claim 1: The control unit controls operation in a cooling priority mode or a white smoke prevention mode, and the cooling priority mode is the An initial cooling step in which the control unit controls the inverter such that the cooling water supplied from the water supply unit heats with the air sucked into the casing through the main intake port from the filling material, and the power of the initial frequency is applied to the blowing motor; And the inverter, so that the frequency of the power applied to the blowing motor gradually increases from the initial frequency until the outlet temperature of the coolant sensed by the temperature sensor decreases below a preset first reference temperature. Cooling control step of controlling the; Including, and the white smoke prevention mode, the control unit, the white smoke determination step of determining whether or not the white smoke generated by the air discharged to the outside of the casing through the exhaust port; And a white smoke control step in which the control unit controls the damper to be opened to suck air into the casing through the auxiliary air intake. It includes.

In one aspect of the embodiment of the present invention, in the cooling control step, in the cooling priority mode, the inverter is controlled such that the frequency of the power applied to the blowing motor is increased in a range not exceeding a predetermined maximum frequency.

In an aspect of the embodiment of the present invention, in the white smoke determination step, the control unit determines the height of the white smoke in the image of the white smoke generated by air discharged to the outside of the casing through the exhaust port photographed by the vision camera. It is determined that white smoke is generated only when it is determined that the height is higher than or equal to the set height.

In an aspect of an embodiment of the present invention, in the white smoke control step, the controller determines the degree of white smoke in proportion to the height of the white smoke in the image photographed by the vision camera, and is proportional to the amount of white smoke generated. The damper is controlled so that the opening degree is increased.

In one aspect of the embodiment of the present invention, in the white smoke control step, the control unit, when the damper is open, when the outlet temperature of the coolant detected by the temperature sensor is lowered below the first reference temperature The inverter is controlled so that the frequency of the power applied to the blowing motor increases until the outlet temperature of the cooling water sensed by the temperature sensing sensor before the frequency of the power applied to the blowing motor reaches a preset maximum frequency. When the temperature falls below the first reference temperature, the inverter is controlled so that the power of the frequency at that time is applied to the blowing motor, and the temperature is applied even if the frequency of the power applied to the blowing motor reaches a preset maximum frequency. When the outlet temperature of the coolant sensed by the detection sensor exceeds the first reference temperature, the damper is controlled to reduce the opening degree.

In one aspect of the embodiment of the present invention, in the white smoke control step, the control unit, when the outlet temperature of the coolant detected by the temperature sensor in the process of reducing the opening degree of the damper reaches the first reference temperature, The damper is controlled so that the opening degree at that point is maintained.

In one aspect of the embodiment of the present invention, in the white smoke control step, the controller, the opening temperature of the coolant sensed by the temperature sensor while the opening degree of the damper is maintained, is preset to be less than the first reference temperature. When the temperature falls below the second reference temperature, the inverter is controlled so that the frequency of the power applied to the blowing motor is reduced, or the damper is controlled so that the opening degree is increased.

In one aspect of the embodiment of the present invention, in the white smoke control step, the control unit, the outlet temperature of the coolant detected by the temperature sensor while the opening degree of the damper is maintained is lowered below the second reference temperature In the case, when the height of white smoke in the image photographed by the vision camera is reduced or maintained, the outlet temperature of the coolant sensed by the temperature sensor increases above the second reference temperature and below the first reference temperature. The inverter is controlled so that the frequency of the power applied to the blower motor decreases until it is done, and the damper is controlled so that the opening degree is maintained.

In one aspect of the embodiment of the present invention, in the white smoke control step, the control unit, the outlet temperature of the coolant detected by the temperature sensor while the opening degree of the damper is maintained is lowered below the second reference temperature In the case, when the height of white smoke in the image photographed by the vision camera increases, when the outlet temperature of the coolant detected by the temperature sensor increases above the second reference temperature and below the first reference temperature The inverter is controlled so as to maintain the frequency of the power applied to the blower motor, and the damper is controlled to increase the opening degree.

In the cooling tower and the control method according to an embodiment of the present invention, in the cooling priority mode, the frequency of the power applied to the blower motor is varied so that the outlet temperature of the cooling water reaches a preset first reference temperature, and the damper in the anti-fogging mode To prevent white smoke, but when the outlet temperature of the coolant exceeds the first reference temperature even when the frequency of the power applied to the blower motor is at the maximum frequency, by adjusting the opening degree of the damper, the outlet temperature of the coolant is the first. It is controlled to maintain the reference temperature. In addition, in the present embodiment, since it is determined that the white smoke is generated when the height of the white smoke is greater than or equal to a predetermined reference height in the image of the white smoke, efficient prevention of the white smoke acting as visual pollution can be achieved.

1 is a longitudinal sectional view showing a cooling tower according to an embodiment of the present invention.
Figure 2 is a schematic view showing an embodiment of the present invention.
Figure 3 is a flow chart showing a cooling tower control method according to an embodiment of the present invention.

Hereinafter, a configuration of a cooling tower according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a longitudinal sectional view showing a cooling tower according to an embodiment of the present invention, Figure 2 is a schematic view showing an embodiment of the present invention.

Referring to FIG. 1, the cooling tower 1 according to the present embodiment includes a casing 100, a water supply part 200, a blower part 300, a filling material 400, a water collecting part 500, and a temperature sensor 700 ) And the control unit 900. The casing 100 defines a predetermined space in which component parts constituting the cooling tower 1 are installed. In addition, the water supply unit 200 serves to supply cooling water as a heat exchange target. The blower 300 serves to flow air that is heat exchanged with the cooling water. The filling material 400 is a place where heat exchange between cooling water supplied from the water supply part 200 and air flowed by the blowing part 300 is made, and the collecting part 500 is provided by the filling material 400. This is where the heat exchanged coolant is collected. The control unit 900 is to drive the cooling tower 1, in particular, in this embodiment, the control unit 900, the outlet temperature of the cooling water detected by the temperature sensor 700 and / and white smoke Depending on whether it occurs, the operation is controlled in the cooling priority mode or the anti-fog mode.

More specifically, the casing 100 is defined as an external appearance, and is formed in a predetermined shape including at least both side surfaces and an upper surface, for example, a hexahedral shape. The casing 100 is formed with a main intake port 111, an auxiliary intake port 112, and an exhaust port 120. The main intake port 111 and the auxiliary intake port 112 are places where air is sucked into the casing 100, and the exhaust port 120 is where air is discharged out of the casing 100. In the present embodiment, the main intake port 111 is located on both sides of the casing 100, the auxiliary intake port 112, both sides of the casing 100 corresponding to the upper side of the main intake port 111 Located in the, the exhaust port 120 is located in the center of the upper surface of the casing 100.

In addition, a fan stack 130 is provided on the upper surface of the casing 100. The fan stack 130 serves to guide air discharged through the exhaust port 120. The fan stack 130 may be formed in a polyhedron, for example, a cylindrical shape, extending upwardly by a predetermined length from the upper surface of the casing 100 and opening the upper and lower surfaces.

The water supply part 200 includes a pair of water supply pipes 210 and a nozzle 220. The water supply pipe 210 is a place to receive cooling water to be exchanged with air. And the nozzle 220 is a place where the cooling water supplied to the water supply pipe 210 is sprayed toward the filling material 400. In this embodiment, the water supply unit 200 is composed of a pair located on both sides of the inner casing 100 corresponding to the main intake port 111 and the auxiliary intake port 112.

Meanwhile, the blower 300 includes a blower fan 310, a blower motor 320, and an inverter 330. The blowing fan 310 serves to flow air to the inside and outside of the casing 100. That is, when the blowing fan 310 is rotated, air drawn into the casing 100 through the main intake port 111 exchanges heat with cooling water, and the casing 100 through the auxiliary intake port 112. The air sucked into the interior of the casing 100 is sucked into the casing 100 through the main intake port 111 and mixed with the heat exchanged with the cooling water. In addition, when the blowing fan 310 rotates, the casing 100 is sucked into the interior of the casing 100 through the main intake port 111 and heat exchanged with cooling water or through the auxiliary intake port 112. The air mixed with the air sucked into the air is discharged to the outside of the casing 100 through the exhaust port 120. As the blowing fan 310, for example, an axial fan may be used. The blowing motor 320 provides driving force for rotation of the blowing fan 310. In addition, the inverter 330 includes an inverter 330 that controls the frequency of the power applied to the blowing motor 320. Practically, when the frequency of the power applied to the blowing motor 320 is increased by the inverter 330, the number of revolutions of the blowing fan 310 will increase.

Meanwhile, the filling material 400 is located inside the casing 100 corresponding to the main intake port 111 and the water supply unit 200. Therefore, the cooling water sprayed from the nozzle 220 flows along the surface of the filler 400 or the space between the filler 400 and is exchanged with the air sucked through the main intake 111.

Cooling water heat-exchanged with air is collected in the water collecting part 500 while flowing along the surface of the filling material 400. The water collecting part 500 is installed under the casing 100 corresponding to the lower side of the main intake port 111. The cooling water collected in the water collecting part 500 is discharged to the outside to circulate other facilities.

In addition, the cooling tower 1 may further include a damper 600. The damper 600 selectively opens and closes the auxiliary intake port 112 and adjusts the opening degree of the auxiliary intake port 112.

And, the temperature sensor 700 detects the temperature of the cooling water. In this embodiment, the temperature sensing sensor 700 detects the outlet temperature of the coolant that is collected by the water collecting part 500 and discharged to the outside.

Meanwhile, in the cooling priority mode, the control unit 900 controls the inverter 330 according to the outlet temperature of the cooling water sensed by the temperature detection sensor 700. In addition, in the white smoke reduction mode, the control unit 900 determines whether white smoke is generated by the air discharged to the outside of the casing 100 through the exhaust port 120 and the cooling water detected by the temperature sensor 700. The inverter 330 and the damper 600 are controlled according to the outlet temperature.

More specifically, the control unit 900, in the cooling priority mode, until the outlet temperature of the cooling water sensed by the temperature sensor 700 is lowered below a preset first reference temperature, the blowing motor 320 ), the inverter 330 is controlled so that the frequency of the power applied to it gradually increases from the initial frequency. For example, when the initial frequency is 30 Hz and the first reference temperature is 32° C., the control unit 900 is connected to the blowing motor 320 until the outlet temperature of the cooling water decreases below 32° C. The inverter 330 may be controlled so that the frequency of the applied power is gradually increased at 30 Hz. In addition, when the outlet temperature of the cooling water sensed by the temperature sensor 700 decreases below the first reference temperature, the control unit 900 supplies power to the air blower motor 320 at that time. The inverter 330 may be controlled to be applied. At this time, the controller 900 controls the inverter 330 so that the frequency of the power applied to the blowing motor 320 is increased in a range not exceeding a preset maximum frequency. Here, the maximum frequency may be set to, for example, 60 Hz. That is, in the cooling priority mode, the control unit 900 controls the inverter 330 such that the number of revolutions of the blowing fan 310 gradually increases to the maximum number of revolutions so as to ensure cooling performance of the cooling water.

Meanwhile, the cooling tower 1 may further include a vision camera 800 that photographs an image of white smoke generated by air discharged to the outside of the casing 100 through the exhaust port 120. In addition, the controller 900 may control the operation in the anti-fogging mode only when the height of the white smoke in the image photographed by the vision camera 800 is determined to be equal to or greater than a preset height. In other words, the control unit 900 determines whether white smoke is generated according to the height of the white smoke in the image photographed by the vision camera 800. Here, the operating conditions for the white smoke prevention mode may be set according to the installation location or capacity of the cooling tower 1 or the driver's selection. In addition, in the anti-fogging mode, the control unit 900 determines the degree of occurrence of white smoke in proportion to the height of the white smoke in the image photographed by the vision camera 800, and the opening degree is proportional to the occurrence of white smoke. The damper 600 is controlled to increase.

In addition, the control unit 900, even in the anti-fogging mode, in the state in which the damper 600 is open, the outlet temperature of the coolant detected by the temperature sensor 700 may reach a preset first reference temperature. The inverter 330 is controlled so that the frequency of the power applied to the blowing motor 320 is increased until. In addition, when the outlet temperature of the cooling water sensed by the temperature sensor 700 decreases below the first reference temperature, the control unit 900 supplies power to the air blower motor 320 at that time. The inverter 330 may be controlled to be applied.

In particular, in this embodiment, the control unit 900, in the white smoke prevention mode, even if the frequency of the power applied to the blowing motor 320 reaches the maximum frequency is detected by the temperature sensor 700 When the outlet temperature of the cooling water exceeds the first reference temperature, the damper 600 is controlled to reduce the opening degree. In other words, even if it is determined that white smoke has occurred, the control unit 900 rotates the blower fan 310 at a maximum rotational speed to cool the cooling water, but the outlet temperature of the cooling water is below the first reference temperature. If not, it is to control the operation of the cooling tower 1 in order to secure cooling performance of cooling water rather than preventing white smoke.

In addition, when the opening temperature of the coolant detected by the temperature sensor 700 decreases in the process of reducing the opening degree of the damper 600 in the white smoke prevention mode, the control unit 900 falls below the first reference temperature. , The damper 600 is controlled to maintain the opening degree at that time. That is, the controller 900 controls the operation of the cooling tower 1 to prevent the white smoke from being cooled to the extent that the cooling water cooling performance is secured in a state where white smoke is tolerated in order to secure the cooling performance of the cooling water. do.

Next, the control unit 900, in the anti-fogging mode, the outlet temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained is less than the first reference temperature. When the temperature falls below a preset second reference temperature, the inverter 330 is controlled so that the frequency of the power applied to the blowing motor 320 is reduced, or the damper 600 is controlled to increase the opening degree. In other words, when the cooling performance of the cooling water is sufficiently secured and the overcooling of the cooling water is concerned, the control unit 900 decreases the number of revolutions of the blowing fan 310 or increases the opening degree to prevent white smoke. The damper 600 is controlled. For example, the second reference temperature may be set to 28°C.

More specifically, the control unit 900, in the white smoke prevention mode, the outlet temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained, the second reference temperature When the height of white smoke in the image photographed by the vision camera 800 is reduced or maintained when it is lowered below, the outlet temperature of the coolant sensed by the temperature sensor 700 is the second reference temperature. The inverter 330 is controlled so that the frequency of the power applied to the blower motor 320 is reduced until the temperature rises above and below the first reference temperature, and the damper 600 is controlled to maintain the opening degree. . In other words, when it is determined that the white smoke is reduced or maintained, the control unit 900 controls the rotational speed of the blower fan 310 to be reduced in order to save energy while the opening degree of the damper 600 is maintained. do.

On the other hand, the control unit 900, in the anti-fogging mode, the outlet temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained is less than the first reference temperature. When the height of the white smoke in the image photographed by the vision camera 800 is increased in the case of deterioration, the outlet temperature of the coolant sensed by the temperature sensor 700 is greater than or equal to the second reference temperature and the agent Until the temperature rises below 1 reference temperature, the inverter 330 is controlled so that the frequency of the power applied to the blowing motor 320 is maintained, and the damper 600 is controlled to increase the opening degree. In other words, when it is determined that the white smoke is to be increased, the controller 900 controls the opening degree of the damper 600 to be increased in order to reduce the white smoke while the blowing fan 310 rotates at the maximum rotational speed. do.

Hereinafter, a cooling tower control method according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

3 is a flowchart showing a cooling tower control method according to an embodiment of the present invention.

First, when the cooling process of the cooling water in the cooling tower 1 is described, when the blowing fan 310 is rotated by the blowing motor 320, the air drawn into the casing 100 through the main intake port 111 is The filling material 400 is passed. And the air that has passed through the filling material 400 by continuous rotation of the blowing fan 310 is discharged to the outside of the casing 100 through the exhaust port 120.

Meanwhile. When the cooling water supplied to the water supply part 200 and the water supply pipe 210 is sprayed through the nozzle 220, the heat exchange is made by contacting the air sucked through the main intake port 111 while passing through the filling material 400 do. In addition, the cooling water heat-exchanged with the air in the filling material 400 is collected in the water collecting part 500. Practically, the air heat-exchanged with the air in the filler 400 is guided by the water collecting guide 510 and is collected in the water collecting tank 520.

Next, when the process of preventing white smoke in the cooling tower 1 is described, when the auxiliary air intake 112 is opened by the damper 600, when the blowing fan 310 is rotated, the auxiliary intake 112 is turned on. Air is sucked through the casing 100. In addition, air sucked into the casing 100 through the auxiliary intake port 112 is sucked into the casing 100 through the main intake port 111 and heat exchanged with cooling water in the filler 400. After being mixed with air, it is discharged to the outside of the casing 100 through the exhaust port 120.

Referring to FIG. 3, in the present embodiment, the control unit 900 controls the cooling tower 1 to operate in a cooling priority mode or a white smoke prevention mode. In practice, in the cooling priority mode, the control unit 900 controls the operation of the cooling tower 1 to ensure cooling performance of cooling water, and in the anti-fogging mode, the control unit 900 prevents white smoke. And controlling the operation of the cooling tower 1 so that cooling performance of cooling water is properly achieved.

More specifically, the cooling priority mode includes an initial cooling step (S100) and a cooling control step (S200). In the initial cooling step (S100), the control unit 900, the cooling water supplied from the water supply unit 200 is sucked into the interior of the casing 100 from the filler 400 through the main intake port 111 The inverter 330 is controlled so that power of an initial frequency is applied to the blowing motor 320 to exchange heat with the air. Next, in the cooling control step (S200), the control unit 900, until the outlet temperature of the cooling water sensed by the temperature sensor 700 is lowered below a predetermined first reference temperature, the blowing motor The inverter 330 is controlled so that the frequency of the power applied to 320 is gradually increased from the initial frequency. In other words, in the initial cooling step (S100) and the cooling control step (S200), after the cooling of the cooling water is started, the control unit 900 starts the blowing fan 310 so that the outlet temperature of the cooling water reaches the first reference temperature. It is controlled so that the number of revolutions of) gradually increases in the range below the maximum number of revolutions. In addition, when the outlet temperature of the cooling water sensed by the temperature sensor 700 decreases below the first reference temperature, the control unit 900 applies power of the frequency at that time to the blowing motor 320. The inverter 330 is controlled as much as possible.

Meanwhile, the white smoke prevention mode includes a white smoke determination step (S300) and a white smoke control step (S400). In the white smoke determination step (S300), the control unit 900 determines whether white smoke is generated by air discharged to the outside of the casing 100 through the exhaust port 120. And in the white smoke control step (S400), the control unit 900, the damper 600 so as to open to suck air into the interior of the casing 100 through the auxiliary intake port 112 to prevent white smoke To control.

More specifically, in the white smoke determination step (S300), the control unit 900 is generated by air discharged to the outside of the casing 100 through the exhaust port 120 photographed by the vision camera 800. It is determined that the white smoke is generated only when the height of the white smoke in the image of the white smoke is determined to be greater than or equal to a preset height. In addition, in the white smoke control step (S400), the control unit 900 determines the degree of white smoke generation in proportion to the height of the white smoke in the image photographed by the vision camera 800, and determines the white smoke generation degree. The damper 600 is controlled to increase in proportion to the opening degree.

On the other hand, in the white smoke control step (S400), the control unit 900, in the state in which the damper 600 is open, the first reference to the outlet temperature of the coolant detected by the temperature sensor 700 is preset The inverter 330 is controlled to increase the frequency of the power applied to the blowing motor 320 until the temperature is reached, and the outlet temperature of the coolant detected by the temperature sensor 700 is the first criterion. When the temperature falls below the temperature, the inverter 330 is controlled so that the power of the frequency at that time is applied to the blowing motor 320, thereby ensuring cooling performance of the cooling water. And in the white smoke control step (S400), the control unit 900, even if the frequency of the power applied to the blowing motor 320 reaches a preset maximum frequency, the cooling water detected by the temperature sensor 700 When the outlet temperature of the temperature exceeds the first reference temperature, the damper 600 is controlled to reduce the opening degree, so that cooling performance of the cooling water is secured even when white smoke is generated.

Next, in the white smoke control step (S400), the control unit 900, the outlet temperature of the cooling water detected by the temperature sensor 700 in the process of reducing the opening degree of the damper 600 is the first When the temperature falls below the reference temperature, the damper 600 is controlled to maintain the opening degree at that time. And in the white smoke control step (S400), the control unit 900, the outlet temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained is less than the second reference temperature If it is lowered, the inverter 330 is controlled so that the frequency of the power applied to the blower motor 320 is reduced, or the damper 600 is controlled so that the opening degree is increased. That is, in the white smoke control step (S400), when the height of the white smoke in the image photographed by the vision camera 800 is reduced or maintained, the control unit 900 senses the temperature by the temperature sensor 700. The inverter 330 is controlled so that the frequency of the power applied to the blowing motor 320 decreases until the outlet temperature of the cooled water rises above the second reference temperature and below the first reference temperature, and the opening degree The damper 600 is controlled so as to be maintained. In addition, in the white smoke control step (S400), when the height of the white smoke in the image photographed by the vision camera 800 is increased, the controller 900 cools water sensed by the temperature sensor 700. The inverter 330 is controlled to maintain the frequency of the power applied to the blowing motor 320 until the outlet temperature of the temperature rises above the second reference temperature and below the first reference temperature, and the opening degree increases. The damper 600 is controlled as much as possible. Therefore, in the white smoke control step (S400), sufficient cooling water cooling performance is secured in consideration of whether white smoke is generated or the degree of white smoke, and at the same time, it is possible to cope with white smoke.

Many other modifications are possible to a person having ordinary knowledge in the art within the scope of the basic technical idea of the present invention, and the scope of the present invention should be interpreted based on the appended claims. .

In this embodiment, the counter-flow type of the cooling tower is described as an example, but it will be apparent that the present invention is applicable to a cross-flow type or other type of cooling tower.

1: cooling tower 100: casing
111: primary intake 112: secondary intake
200: water supply unit 300: blower
310: blowing fan 320: blowing motor
330: inverter 400: filling material
500: water collecting part 600: damper
700: temperature sensor 800: vision camera
900: control unit

Claims (18)

The main intake port 111 through which the air heat-exchanged with the cooling water is sucked, the auxiliary intake port 112 through which the air in which the heat-exchanged air is mixed is sucked, and the air sucked through the main intake port 111 and exchanged with the cooling water The casing 100 is formed with an exhaust port 120 through which air mixed with air sucked through the auxiliary intake port 112 is discharged;
A water supply unit 200 supplying cooling water that is heat-exchanged with the air sucked through the main intake port 111;
Blowing fan 310 that is sucked into the casing 100 through the main intake port 111 and discharged to the outside of the casing 100 through the exhaust port 120 to form a flow of air heat exchanged with cooling water , A blower 300 including a blower motor 320 for rotating the blower fan 310 and an inverter 330 for controlling the frequency of power applied to the blower motor 320;
A filling material 400 in which heat exchanged between the air sucked into the casing 100 and the cooling water supplied from the water supply part 200 through the main intake port 111;
A collecting unit 500 in which cooling water exchanged with air in the filling material 400 is collected;
A damper 600 for selectively opening and closing the auxiliary intake port 112;
A temperature sensor 700 for sensing the outlet temperature of the cooling water discharged from the water collecting part 500 to the outside; And
Further comprising a control unit 900 for controlling the operation,
The control unit 900,
White smoke by air discharged to the outside of the casing 100 through the cooling priority mode or the exhaust port 120 that controls the inverter 330 according to the outlet temperature of the coolant sensed by the temperature sensor 700. Controlling the operation in a white smoke prevention mode to control the inverter 330 and the damper 600 according to whether it occurs and the outlet temperature of the coolant detected by the temperature sensor 700,
In the white smoke prevention mode,
In the state in which the damper 600 is open, power of the power applied to the blowing motor 320 until the outlet temperature of the coolant detected by the temperature sensor 700 falls below a preset first reference temperature. Control the inverter 330 to increase the frequency,
If the outlet temperature of the coolant sensed by the temperature sensor 700 falls below the first reference temperature before the frequency of the power applied to the blowing motor 320 reaches a preset maximum frequency, at that point The frequency of the power is applied to the blower motor 320 to control the inverter 330,
Even if the frequency of the power applied to the blower motor 320 reaches a preset maximum frequency, when the outlet temperature of the coolant detected by the temperature sensor 700 exceeds the first reference temperature, the temperature is sensed A cooling tower that controls the damper 600 so that the opening degree is reduced until the temperature of the cooling water sensed by the sensor 700 falls below the first reference temperature.
According to claim 1,
The control unit 900,
In the cooling priority mode, the frequency of the power applied to the blowing motor 320 gradually increases from the initial frequency until the outlet temperature of the cooling water sensed by the temperature sensor 700 falls below a preset first reference temperature. Control the inverter 330 to increase to,
When the outlet temperature of the coolant sensed by the temperature sensor 700 falls below the first reference temperature, the inverter 330 is controlled so that the power of the frequency at that time is applied to the blowing motor 320. Cooling tower.
According to claim 2,
The control unit 900,
In the cooling priority mode, the cooling tower that controls the inverter 330 so that the frequency of the power applied to the blowing motor 320 is increased in a range not exceeding a predetermined maximum frequency.
According to claim 1,
Further comprising a vision camera 800 for photographing the image of the white smoke generated by the air discharged to the outside of the casing 100 through the exhaust port 120,
The control unit 900, the cooling tower to control the operation in the white smoke prevention mode only when it is determined that the height of the white smoke in the image taken by the vision camera 800 is greater than or equal to a preset height.
The method of claim 4,
The control unit 900,
In the white smoke prevention mode, the degree of white smoke is determined in proportion to the height of the white smoke in the image photographed by the vision camera 800, and the damper 600 is controlled to increase the opening degree in proportion to the white smoke occurrence. Cooling tower.
delete The method of claim 4,
The control unit 900,
In anti-fogging mode,
If the outlet temperature of the coolant sensed by the temperature sensor 700 decreases below the first reference temperature in the process of reducing the opening degree of the damper 600, the damper 600 is maintained to maintain the opening degree at that time. Cooling tower to control ).
The method of claim 7,
The control unit 900,
In anti-fogging mode,
If the outlet temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained is lower than the second reference temperature set below the first reference temperature, the blowing motor ( 320) a cooling tower that controls the inverter 330 so that the frequency of the power applied to it is reduced or controls the damper 600 so that the opening degree is increased.
The method of claim 8,
The control unit 900,
In anti-fogging mode,
When the outlet temperature of the coolant sensed by the temperature sensor 700 is lowered below the second reference temperature while the opening degree of the damper 600 is maintained, the vision camera 800 photographs When the height of the white smoke in the image is reduced or maintained, the blower motor (til the outlet temperature of the coolant sensed by the temperature sensor 700 rises above the second reference temperature and below the first reference temperature) 320) to control the inverter 330 to reduce the frequency of the power applied to the cooling tower, and to control the damper 600 to maintain the opening degree.
The method of claim 8,
The control unit 900,
In anti-fogging mode,
When the outlet temperature of the coolant sensed by the temperature sensor 700 is lowered below the second reference temperature while the opening degree of the damper 600 is maintained, the vision camera 800 photographs When the height of the white smoke in the image increases, the blowing motor 320 until the outlet temperature of the coolant sensed by the temperature sensor 700 rises above the second reference temperature and below the first reference temperature. Cooling tower that controls the inverter 330 to maintain the frequency of the power applied to the, and controls the damper 600 so that the opening degree is increased.
In the method for controlling the cooling tower (1) of claim 1:
The control unit 900 controls the operation in a cooling priority mode or a white smoke prevention mode,
The cooling priority mode,
The blower motor so that the control unit 900 exchanges cooling water supplied from the water supply unit 200 with air drawn into the casing 100 from the filling material 400 through the main intake port 111. 320) the initial cooling step of controlling the inverter 330 so that the power of the initial frequency is applied (S100); And
The frequency of the power applied to the blower motor 320 until the control unit 900 lowers the coolant outlet temperature detected by the temperature sensor 700 below a preset first reference temperature is the initial temperature. A cooling control step (S200) of controlling the inverter 330 to be gradually increased in frequency; Including,
The white smoke prevention mode,
The control unit 900, a white smoke determination step (S300) for determining whether the white smoke generated by the air discharged to the outside of the casing 100 through the exhaust port 120; And
A white smoke control step in which the control unit 900 controls the damper 600 to be opened to suck air into the casing 100 through the auxiliary intake port 112 (S400); Including,
In the white smoke control step (S400),
The control unit 900, in the state in which the damper 600 is open, the blower motor 320 until the outlet temperature of the coolant detected by the temperature sensor 700 falls below the first reference temperature ) To control the inverter 330 so that the frequency of the power applied to it is increased, the frequency of the power applied to the blowing motor 320 is detected by the temperature sensor 700 before reaching a predetermined maximum frequency. When the outlet temperature of the cooled water drops below the first reference temperature, the inverter 330 is controlled so that the power of the frequency at that time is applied to the blowing motor 320, and is applied to the blowing motor 320. If the outlet temperature of the coolant sensed by the temperature sensor 700 exceeds the first reference temperature even if the frequency of the power to be reached reaches a preset maximum frequency, the damper 600 is controlled so that the opening degree is reduced. Cooling tower control method.
The method of claim 11,
In the cooling control step (S200),
In the cooling priority mode, the cooling tower control method for controlling the inverter 330 so that the frequency of the power applied to the blowing motor 320 is increased in a range not exceeding a predetermined maximum frequency.
The method of claim 11,
In the white smoke determination step (S300),
The controller 900, the height of the white smoke in the image of the white smoke generated by the air discharged to the outside of the casing 100 through the exhaust port 120 taken by the vision camera 800 is higher than a preset height Cooling tower control method to determine that the white smoke is generated only when determined.
The method of claim 13,
In the white smoke control step (S400),
The control unit 900 determines the degree of occurrence of white smoke in proportion to the height of white smoke in the image photographed by the vision camera 800, and the damper 600 so that the opening degree increases in proportion to the degree of white smoke generation Cooling tower control method to control.
delete The method of claim 13,
In the white smoke control step (S400),
When the outlet temperature of the coolant sensed by the temperature sensor 700 reaches the first reference temperature in the process where the opening degree of the damper 600 is reduced, the control unit 900 opens the opening degree at that time. Cooling tower control method for controlling the damper 600 to be maintained.
The method of claim 16,
In the white smoke control step (S400),
The control unit 900, the outlet temperature of the cooling water sensed by the temperature sensor 700 while the opening degree of the damper 600 is maintained is below the first reference temperature and below a preset second reference temperature. When it is lowered, the cooling tower control method for controlling the inverter 330 so that the frequency of the power applied to the blowing motor 320 is reduced or the damper 600 is controlled to increase the opening degree.
The method of claim 17,
In the white smoke control step (S400),
The control unit 900, when the opening temperature of the coolant detected by the temperature sensor 700 while the opening degree of the damper 600 is maintained, decreases below the second reference temperature, the vision camera When the height of the white smoke in the image photographed by 800 is decreased or maintained, the outlet temperature of the coolant detected by the temperature sensor 700 rises above the second reference temperature and below the first reference temperature. Cooling tower control method for controlling the inverter 330 so that the frequency of the power applied to the blower motor 320 is reduced, and the damper 600 is maintained so that the opening degree is maintained until.

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