KR20000012649A - Prevention Apparatus to be Frozen over Ventilation Fan for Cooling Tower - Google Patents

Abstract

PURPOSE: A blower fan freezing prevention device for a cooling tower is provided to prevent a cooling tower from being frozen during the winter by switching the blower fan automatically or manually or by making the fan rotate forward or backward automatically. CONSTITUTION: The blower fan freezing prevention device for a cooling tower comprises; the power supply part(30) to deliver electric power; the power switch(s3) to turn on or off the power outputted from the power supply part(30); the fan motor(35) to rotate forward or backward by the power inputted from the power supply part(30); the backward turn switch(s1) to turn the fan motor(35) backward; the forward turn switch(s2) to turn the fan motor(35) forward; the choice switch(s4) to set-up mode of the run of the fan motor(35) automatic or manual; the transfer switch(s5) to transfer the running of the fan motor(35) to automatic or manual.

Description

Freezing prevention device of cooling fan for cooling tower {Prevention Apparatus to be Frozen over Ventilation Fan for Cooling Tower}

The present invention relates to a device for preventing freezing of a cooling fan for a cooling tower, and more particularly, in order to prevent freezing of a cooling tower of a cooling device used for cooling or cooling of a building or an apparatus or a device in winter. The present invention relates to an apparatus for preventing a freezing of a blower fan for a cooling tower to switch automatically or manually or to automatically rotate forward or reverse.

An air conditioner is installed in an interior of a building, an apparatus, or a device that requires cooling, and uses a refrigerant (coolant) to take away heat from the surroundings and lower the temperature. Such a cooling device is installed and operated in a summer or low humidity area.

In particular, in the place where constant temperature and humidity must be maintained during the four seasons such as the computer room, the air conditioner is used even in the winter season.

Conventionally, such a cooling device is shown in the cooling tower and piping system diagram of FIG. 1. It consists of a piping system consisting of a supply pipe 18 and the discharge pipe 18 is supplied or discharged between the cooling water.

The cooling device is the cooling water heat exchanged from the room or the device such as the heat load 22 is sucked through the discharge pipe 18 is introduced through the inlet 15 of the cooling tower 10, the cooling tower 10 is the discharge pipe (18) The cooling water introduced through the spray nozzle 13 is sprayed through the spray nozzle 13 configured at the upper end of the cooling tower 10, and the injected cooling water is cooled by the air sucked from the vent 14 by the driving of the blower fan 11. The cooled coolant is filtered through the filler 12, and flows through the passage of the filler 12 to cool it further. Since the passage of the coolant and air passes through the passage of the filler 12, the surface area of the coolant is widened and cooled through the passage. In addition, the coolant passing through the filler 12 is collected in the water tank 17 formed at the lower end of the cooling tower 10, and the coolant collected in the water tank 17 is supplied to the supply pipe through the outlet 16 by driving the motor pump 20. Since it is supplied to 18, heat exchange is again performed at the heat load 22.

As described above, the cooling water continues to exchange heat and flow into and out of the cooling tower 10 and the heat load 22 of the air conditioner to cool the heat load 22 to a predetermined temperature. The cooling tower 10 should be installed outdoors, in particular, a rooftop to facilitate cooling, and is preferably spaced apart from other installations by a predetermined distance. Also, the installation does not generate hot heat or foreign matter. Cooling tower efficiency is high.

Cooling devices are generally used in the summer, but are often used in the winter in order to maintain an appropriate temperature in the room or a corresponding device.

As described above, the cooling water sprayed from the spray nozzle to cool the cooling water in the cooling tower is conventionally cooled by the driving of the blower fan, which cools the coolant by blowing air introduced through the ventilation hole into the blower fan.

When the cooling tower is driven without stopping during the winter, there is almost no freezing phenomenon.However, when the cooling tower is driven at a predetermined time interval, the blowing fan and the vent are easily blown by the freezing steam or water from the cooling tower. As a result, the cooling efficiency of the cooling tower may be lowered or the loss of the cooling tower, in particular, the blower fan. In addition, the outer wall and the surrounding floor of the cooling tower was frozen, there are many problems such as the inspection and maintenance of the cooling tower is not easy.

The present invention, in order to solve the above problems, in the summer to rotate the blower fan of the cooling tower forward so that the air introduced from the vent is discharged to the top of the cooling tower, in the winter season, the blower fan at a predetermined time interval and reverse An object of the present invention is to provide an icing preventing device for a cooling fan blower fan for alternately driving rotation to prevent icing around a cooling fan or a blower or a cooling tower.

1 is a general cooling tower and piping system;

Figure 2 is an electrical wiring diagram of the ice preventing device of the cooling fan for the cooling tower according to the present invention.

♣ Explanation of symbols for main part of drawing ♣

10: cooling tower 11: blower fan

12: Filling material 13: Spray nozzle

14: vent 15: cooling water inlet

16: cooling water outlet 17: water tank

18: discharge pipe 19: supply pipe

20: motor pump 22: heat load

30: power supply 31: electronic relay

32: timer 33: timer setting section

35: fan motor S1: reverse rotation switch

S2: forward switch S3: power switch

S4: selector switch S5: selector switch

S6: disconnect switch

The present invention provides a power supply unit for supplying a predetermined level of power, a power switch for turning on or off the power output from the power supply unit for the above purpose, a fan motor that rotates forward and backward with the power input from the power supply unit, and Reverse rotation switch for rotating the fan motor, forward rotation switch for forward rotation of the fan motor, selection switch for setting the fan motor to be driven manually or automatically, forward rotation or A switching switch for switching the reverse rotation, a timer for outputting a control signal after counting a predetermined time, a timer setting unit for setting the counted time of the timer, and a shutoff switch for stopping the driving of the fan motor. It is characterized by being made.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is an electrical wiring diagram of the icing prevention device of the cooling fan blower fan according to the present invention, and for the description of the present invention uses the same configuration and code of the conventional cooling device.

The power supply unit 30 is a component for supplying a predetermined level of power, using an AC power input (eg, AC220V) input from the outside, and a circuit for blocking or shielding a surge voltage or a noise component included in the AC power. It is. Power supplied from the power supply unit 30 is preferably able to supply a predetermined amount of power for driving the cooling device or cooling tower.

The power switch S3 is on or off to supply or cut off the power output from the power supply unit 30 to the cooling tower 10. The power switch S3 is an operation switch for driving the cooling tower 10.

The fan motor 35 is configured at the upper end of the cooling tower 10 to rotate the blower fan 11 forward or reverse with the power input from the power supply unit 30. The fan motor 35 rotates the rotational force of the fan motor 35. Although it is preferable to drive the blowing fan 11 through, it is also possible to drive the blowing fan 11 directly.

Reverse rotation switch (S1) for the reverse rotation of the fan motor 35, the power applied through the reverse rotation switch (S1) is connected to reverse the rotation of the fan motor (35).

On the contrary, the forward rotation switch S2 is for forward rotation of the fan motor 35, and the power applied through the forward rotation switch S2 is connected to forward rotation of the fan motor 35. The reverse rotation switch S1 and the forward rotation switch S2 are configured to have a contact b so as not to be turned on at the same time. When the forward rotation switch S2 is turned on, the reverse rotation switch S1 is turned off and the reverse rotation switch S1 The forward rotation switch S2 is turned on when it turns on.

The selection switch S4 sets the fan motor 35 to be driven manually or automatically. When the selection switch S4 is switched to the manual position, the fan motor 35 only rotates forward and switches to the automatic position. When the fan motor 35 is switched to the forward or reverse rotation.

The changeover switch S5 switches forward or reverse rotation when the selector switch S4 is driven to the automatic position. The changeover switch S5 is a signal input from the timer 32 by the electronic relay 31. It is supposed to switch states.

The timer 32 outputs a control signal after counting the predetermined time, and the timer 32 allows the fan motor 35 to switch between forward rotation and reverse rotation. For example, The fan motor 35 is rotated forward during the time set in the timer 32, and the fan motor 35 is rotated in reverse when the set time of the timer 32 elapses. In addition, when the timer 32 is operated, the fan motor 35 may be reversely rotated or the fan motor 35 may be rotated forward when the set time of the timer 32 elapses.

The timer setting unit 33 sets the counting time of the timer 32, and the timer setting unit 33 may set the day and night by dividing, which is the daytime when the switch S5 is in the forward rotation position. (E.g., AM08: 00 to PM20: 00 or sunrise to sunset), or at night (for example, PM20: 00 to AM08: 00 or sunset) when the switching switch S5 is in the reverse rotation position. Time can be counted, which can be set by the administrator arbitrarily depending on conditions of use or circumstances.

The cutoff switch S6 stops the driving of the fan motor 35. When the fan motor 35 is excessively loaded or an abnormal state occurs due to a failure of the fan motor 35, the fan motor 35 is stopped. ) Is to cut off the power applied.

The function of the ice-preventing device of the cooling fan blower of the present invention configured as described above is as follows.

When heat exchange occurs from the heat load simultaneously with the operation of the air conditioner in order to cool the heat generated from the room for constant temperature and humidity or from an apparatus or apparatus, a cooling tower for cooling the cooling water is driven. At this time, the driving of the cooling device is a motor pump 20 is operated to circulate the cooling water to the discharge pipe 18 and the supply pipe 18, the cooling water discharged from the discharge pipe 18 by the operation of the motor pump 20 is a cooling tower ( It is injected into the cooling tower 10 through the spray nozzle 13 of 10). The sprayed coolant is sucked from the vent 14 by the forward rotation of the blower fan 11 driven by the fan motor 35 and cooled to a predetermined temperature or lower by external air that has risen through the filler 12 and then the water tank. The coolant of the water tank 17 is supplied back to the heat load 22 through the outlet 16 and the supply pipe 18, and is heat-exchanged at the heat load 22.

For the circulation cycle of the cooling water, referring to the electrical wiring diagram of FIG. 2, first, when the normal operation is made except for the winter, the fan motor 35 rotates forward, and the forward rotation of the fan motor 35 is a blowing fan ( 11) rotates forward to suck the outside air through the vent 14, in this case, the power applied from the power supply unit 30 is applied to the fan motor 35 through the forward rotation switch (S2) to the fan motor Rotate (35) forward. That is, the power of the power supply unit 30 is applied to the selection switch S4 through the power switch S3, and the user selects whether to operate the fan motor 35 in the manual mode or the automatic mode with the selection switch S4. Will be chosen. In the manual mode, the applied power is connected to the fan motor 35 to rotate the fan motor 35 forward. However, in the automatic mode, a mode for rotating the fan motor 35 forward or reverse is automatically performed. It will be switched.

The switching switch S5 is automatically switched according to the time set in the timer 32 to determine whether to rotate the fan motor 35 forward or reverse.

That is, when the forward rotation b contact (Rb) is in the ON state in the forward rotation mode by the set current time, the fan motor 35 is forward rotation through the timer 32. At this time, the cutoff switch S6 is always kept in the on state when there is no user's operation.

When the fan motor 35 of the cooling tower 10 rotates forward, normal operation is performed except for nighttime in winter, and outside air is sucked from the ventilation holes 14 and passes through the filling material 12 to the cooling tower 10. The fan motor 35 of the rise to the top of the cooling tower (10).

However, in winter, especially when the temperature of the night or the outside falls below a predetermined temperature, a signal output from the timer 32 is applied to the relay 31 by the set time of the timer 32, and the relay 31 Switch the forwarding mode switching switch S5 to the reverse rotation mode. Accordingly, the b contact Fb in the forward rotation mode is turned on, and the fan motor 35 is reversely rotated.

In consideration of a predetermined time (for example, about 1 to 5 minutes) when the fan motor 35 is stopped in order to prevent an excessive load of the fan motor 35 as the fan motor 35 in the forward rotation is suddenly reversed. Timer 32 is set to reverse rotation. This is done by the timer setting unit 33, and can be set according to a user's request or driving conditions of the cooling tower 10.

The switching switch S5 may be switched between the forward rotation mode and the reverse rotation mode by the count of the time set in the timer 32 and the operation of the relay 31, thereby increasing the efficiency of the cooling tower 10.

When the fan motor 35 of the cooling tower 10 is reversely rotated, since the outside air of the upper part of the cooling tower 10 flows in by the rotation of the fan motor 35, it flows back to the ventilation hole 14 through the filling material 12. It is possible to prevent the phenomenon of freezing around the ventilation hole 14 or around the cooling tower 10 during the winter. Since the air passing through the cooling tower 10 is in a hot state, it can be prevented from freezing, and in particular, the fan motor 35 and the blowing fan 11 can be prevented from freezing, so that the fan motor 35 and the blowing fan ( 11) It can prevent malfunction or excessive load.

Therefore, the cooling tower 10 periodically rotates forward and reverse, thereby minimizing cooling of the cooling water and freezing of the cooling tower 10.

As described above, the icing prevention device for the cooling tower blower fan of the present invention is configured to perform the forward rotation and the reverse rotation periodically at a set time unit, in which the fan motor of the cooling tower performs only the forward rotation, and the present invention is not limited thereto. Those skilled in the art will be able to easily alter or substitute.

As described above, the freezing prevention device of the cooling fan blower fan of the present invention constitutes a manual mode and an automatic mode by a selector switch so that forward and reverse rotation of the blower fan rotated by the fan motor of the cooling tower is performed. It consists of a forward rotation mode and a reverse rotation mode by the timer and the timer setting unit that can arbitrarily drive the rotation of the fan motor and the blowing fan of the cooling tower according to the user's request, indoor or in need of constant temperature and humidity The cooling tower can efficiently control the cooling water exchanged from the device or equipment, and maximize the operation of the cooling tower by preventing freezing of the cooling fan by the cooling water or freezing around the vent and cooling tower. At the same time, it is possible to prevent failure of the cooling tower in advance, and thus the maintenance is effective.

Claims (2)

A power supply unit 30 for supplying a predetermined level of power; Power switch (S3) for turning on or off the power output from the power supply unit 30, A fan motor 35 which rotates forward and backward with power input from the power supply unit 30, Reverse rotation switch (S1) and for rotating the fan motor 35, Forward rotation switch (S2) for forward rotation of the fan motor 35, Selection switch (S4) for setting the fan motor 35 to be driven manually or automatically, A switching switch S5 for switching forward or reverse rotation when the fan motor 35 is automatically driven, A timer 32 for outputting a control signal after counting the set predetermined time; A timer setting unit 33 for setting a counted time of the timer 32; Isolation prevention device of the cooling fan blower fan, characterized in that the fan switch to stop the drive of the motor (35) (S6) is included. The apparatus of claim 1, wherein the changeover switch (S5) switches the state by an electronic relay (31) to a signal input from a timer (32).