KR101288270B1 - Water spray unit for evaporative cooler - Google Patents

Abstract

PURPOSE: A water injection device for an evaporative cooler is provided to control a flow rate of water supplied to a water injection pipe according to driving time, thereby minimizing the generation of bubbles caused by surging a supply pump inside the water injection pipe. CONSTITUTION: A water injection device (1) for an evaporative cooler includes a wet channel (110) of the evaporative cooler, water injection pipes (140), capillary tubes (150), a control unit (500), a bypass pipe, and a bypass valve. The water injection pipe is arranged above the wet channel and receives water from a supply pump (300). The capillary tubes are arranged under the water injection pipes by being extended at a predetermined length to the wet channel and inject the water to the wet channel. The control unit controls the amount of the water supplied from the supply pump to the water injection pipes. The bypass pipe is arranged in an outlet side of the supply pump. The bypass valve opens and closes the bypass pipe. [Reference numerals] (145) Swing driving unit; (500) Control unit

Description

Water spray unit for evaporative cooler

The present invention relates to a water supply device, and more particularly to a water supply device for spraying water to the wet channel side of the evaporative cooler.

In general, an evaporative cooler is a device that cools the surrounding air by using the latent heat of evaporation of water by spraying water into the air. The evaporative cooler is a direct evaporation system that directly injects water into the indoor supply air, an indirect evaporation system that injects water to obtain a low temperature by exchanging the temperature of the indoor supply air with cold air or a low temperature water, and direct evaporation and indirect evaporation. There is a way to combine expressions.

This evaporative cooler has the advantage of cooling without energy input except for the blower. However, in the general evaporative cooler, since the minimum temperature that can be supplied is limited to the wet bulb temperature of the intake air, proper cooling is provided only when the ambient air is hot and dry. If the humidity is high, a sufficient low temperature may not be obtained in this manner.

Evaporative coolers are disclosed in Registered Room No. 0201473, "Coil Type Evaporative Condenser Cooler," Patent Publication No. 2011-0092773, "Hybrid Cooling System," Patent Publication No. 2008-0081050, "Evaporative Cooling System," and the like.

On the other hand, regenerative evaporative cooling is known in the field of evaporative cooling, which can theoretically lower the temperature of the supply air to the dew point temperature rather than the wet bulb temperature of the intake air. Since the dew point temperature is about 2 to 5 ° C. lower than the wet bulb temperature in the summer humidity conditions in summer, when the regenerative evaporation method is applied, the air supply temperature is lower than that of the general evaporation method.

The water supply device of the conventional evaporative cooler sends the water introduced into the water tank through the water supply valve to a water spray pipe installed at the upper portion of the evaporative cooler by operating a circulation pump, wherein the capillary connected to the water spray pipe is provided with a small amount of water. Spray. In order to reduce excessive water consumption, capillaries inject water into the wet channel part by gravity rather than water pressure inside the water spray pipe.

In order to reduce the amount of circulating water in the operation of the above water pump, the valve opening installed on the pump discharge side needs to be reduced. At this time, a surging phenomenon occurs in the pump and a large amount of bubbles are generated. Bubbles in the water spray tube remain inside the capillary tube, preventing water from flowing, and eventually no water flows from the capillary tube. As a result, the water supplied to the wet channel is not uniformly supplied to the front surface. There was a problem of this deterioration.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problem, and to provide a water supply device for an evaporative cooler that can minimize the occurrence of surging phenomenon during operation.

Another object of the present invention is to provide an evaporative cooler water supply device that can minimize the generation of bubbles in the water spray pipe by forming an air discharge pipe in the water spray pipe.

In addition, another object of the present invention is to provide an evaporative cooler water pouring device to reduce the excessive water consumption by uniformly controlling the flow rate supplied to the water spray pipe.

The object of the present invention can be achieved by a pouring device for an evaporative cooler. The water pump of the present invention comprises: a wet channel of the evaporative cooler; A water spray pipe disposed above the wet channel and receiving water from a supply pump; A capillary tube extending in a predetermined length toward a constant wet channel in a lower region of the water spray pipe to inject water into the wet channel; A control unit controlling the amount of water supplied from the supply pump to the water injection pipe; And a bypass valve disposed on the discharge side of the supply pump, and a bypass valve for opening and closing the bypass pipe. The control unit initially operates the supply pump at the maximum rotational speed with the bypass valve closed. When the water spray pipe is full, the bypass valve is opened and the rotation speed of the supply pump is reduced.

According to one embodiment, the water spray pipe is formed with a predetermined length so that the air discharge pipe for discharging the air inside the water spray pipe to the outside toward the wet channel.

According to one embodiment, a heat exchange fin is formed inside the wet channel.

According to one embodiment, the capillary further comprises a swing driving part for rotating the water injection pipe to spray water at a predetermined angle swinging the upper portion of the wet channel.

 The water injection device according to the present invention controls the flow rate supplied to the water spray pipe according to the operation time to minimize the bubbles generated by the supply pump surging inside the water spray pipe, so that the generated bubbles are also smoothly exhausted through the air discharge pipe.

As a result, by continuously spraying a small amount of water into the wet channel to prevent sudden deterioration of the evaporative cooler, the cooling performance can be exhibited under the best conditions.

1 is a schematic diagram showing the overall configuration of the water supply for the cooler according to the present invention,
Figure 2 is a schematic diagram showing the side of the evaporative cooler wet channel of the water injector for the cooler according to the present invention,
Figure 3 is a front view showing the front configuration of the water pump for the cooler according to the present invention,
Figure 4 is an enlarged view showing an enlarged configuration of the air discharge pipe of the water cooling device for a cooler according to the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is a schematic view showing the configuration of a water injection device 1 according to the present invention, Figure 2 is a perspective view showing the water injection unit 100 side of the water injection device (1).

As shown, the water supply apparatus 1 according to the present invention includes a water spray unit 100 for spraying water to the wet channel 110 side of the evaporative cooler, a water tank 200 in which water is stored, and a water tank 200. The supply pump 300 for supplying the water of the water to the water spraying unit 100, the bypass pipe 400 for bypassing a part of the water supplied to the water spraying unit 100, and according to the driving of the water supply apparatus (1) It includes a control unit 500 for controlling the supply pump 300 and the bypass pipe (400).

The water spray unit 100 is connected to the wet channel 110, the water spray pipe 140 disposed on the wet channel 110 and receiving water from the supply pump 300, and the water spray pipe 140. It includes a plurality of capillary tube (150) for injection into the wet channel (110).

Heat exchange fins 130 are formed in the wet channel 110 of the evaporative cooler. A plurality of heat exchange fins 130 are formed to protrude to improve the heat exchange area. The heat exchange fins 130 may be formed in the form of offset fins or may be formed in the form of louver fins.

An air inlet 120 is formed below the wet channel 110. One side of the air inlet 120 is formed with an outlet 113 through which the additional air (A3) is discharged. Air A1 is introduced through the air inlet 120 of the wet channel 110, air A2 is discharged upwards, and additional air A3 is discharged through the outlet 113.

The water spray pipe 140 is connected to the supply pump 300 to receive water. The capillary tube 150 is formed in the lower portion of the water spray tube 140 in the direction of the wet channel 110 to supply a small amount of water to the wet channel 110.

Here, the water spray pipe 140 is rotated to the left and right by the swing drive unit 145. As a result, the capillary tube 150 connected to the lower portion of the water spray tube 140 may spray water to the wet channel 110 more uniformly. The swing driver 145 rotates the water spray pipe 140 by a driving force of a motor (not shown).

The water tank 200 stores water therein. The supply pump 300 supplies water from the water tank 200 to the water spray pipe 140 under the control of the controller 500. The supply pump 300 is driven at the maximum speed during initial operation under the control of the controller 500, and is driven at a speed in the range of 2/3 to 3/4 according to the control of the controller 500 after a certain time. . In general, since the supply pump 300 is selected to be driven at the maximum rotation speed, in order to reduce the flow rate inside the water injection pipe 140, the discharge pipe of the supply pump 300 is resisted, and the rotation speed of the supply pump 300 is adjusted. It should only be reduced by a certain range. This is to prevent the cause of surging because the water supply is reduced when the resistance of the discharge pipe of the supply pump 300 is increased to operate the left downward.

The bypass pipe 400 is connected between the water supply pipe and the water tank 200 to bypass a portion of the water supplied to the water spray pipe 140 to the water tank 200. The bypass valve 400 is connected to the bypass pipe 400 and is opened and closed under the control of the controller 500. The bypass valve 410 is formed as a solenoid valve and is opened and closed by an electrical signal of the controller 500.

The controller 500 controls the amount of water sprayed from the water spray unit 100 to the wet channel 110 to minimize the occurrence of bubbles in the water spray pipe 140 to prevent surging.

To this end, the controller 500 controls the supply pump 300 to be driven at the maximum rotational speed in a state where the bypass valve 410 is closed at the initial time when the water pump 1 is operated. As a result, the water spray pipe 140 is quickly switched to the full water state in the empty state.

The control unit 500 reduces the rotation speed of the supply pump 300 to a range of 1/2 to 2/3 when the water spray pipe 140 is in a full state and opens a bypass valve 410 to bypass a part of the water. Let's do it. Thereby, it is possible to minimize the generation of bubbles due to the surging of the supply pump.

3 and 4 are front and enlarged views showing another embodiment of the water spray unit 100. Water spraying unit 100 according to another embodiment is an air discharge pipe 160 is formed in the water spray pipe 140.

Even if the controller 500 minimizes the occurrence of surging of the supply pump by adjusting the supply flow rate of the supply pump 300 and opening / closing of the bypass valve 410, some bubbles are generated in the water injection pipe 140. The air discharge pipe 160 discharges bubbles remaining in the water spray pipe 140 to the outside to prevent the capillary pipe 153 from being blocked.

Capillary portion 150a according to another embodiment is formed of a connecting tube 151, a distribution tube 153, and a capillary tube 155. Since the distribution pipe 153 is bifurcated from the connection pipe 151, the pressure inside the capillary tube 155 is lowered, so that a small amount of water is injected into the wet channel 110.

At this time, since the water spray pipe 140 is rotated to the left and right by the swing driving unit 145, the capillary tube 150a is also rotated to the left and right. At this time, since the bubbles inside the discharge through the air discharge pipe 160 to the outside, the capillary tube 155 can be continuously and uniformly spray a small amount of water.

Here, the capillary tube 155 and the air discharge pipe 160 is formed in the range of 1.0 ~ 1.5mm in diameter, 90mm ~ 100mm in length.

A process of using the water pouring apparatus 1 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 4.

Before the water injection device 1 starts to operate, the water spray pipe 140 is kept empty. When the operation is started, the control unit 500 rotates the supply pump 300 at the maximum rotational speed and closes the bypass valve 410. When the supply pump 300 rotates at the maximum rotation speed, the water is quickly filled inside the water spray pipe 140.

When the water supply apparatus 1 is operated about 10 minutes normally, the inside of the water spray pipe 140 will be in full water condition. Because the water is filled in the water spray pipe 140 at the moment it can reduce the generation of bubbles. The controller 500 opens the bypass valve 410 to detect a full water level and bypasses a part of the water supplied to the water injection pipe 140 by the supply pump 300 to the water tank 200.

The water of the water injection pipe 140 is injected into the wet channel 110 through the capillary 150. At this time, since the water spray pipe 140 is rotated to the left and right, it can be more uniformly supplied to the plate surface of the wet channel (110).

On the other hand, when operating the water supply apparatus 1 according to the present invention, the time when the capillary is clogged by bubble generation was compared with the conventional water supply apparatus without controlling the flow rate of the supply pump and without installing the bypass pipe. At this time, the remaining conditions including the diameter of the capillary tube were applied in the same manner.

In the conventional water pouring device, water is not injected from 20% of the capillaries after 10 minutes of operation, and 40% of the capillaries is blocked by bubbles after 1 hour, and water is not injected.

On the other hand, in the water supply apparatus according to the present invention, water was not injected at 5% of the capillaries after 50 minutes of operation, and when 2 hours had elapsed, 15% was blocked by bubbles.

Looking at the results of these experiments it can be seen that the water injection device according to the present invention can significantly reduce the surging phenomenon and bubble generation.

1: water injection device 100: water injection unit
110: wet channel 111: spray pipe support plate
113: additional air inlet 120: air intake
130: heat exchange fin 140: water spray pipe
145: swing drive 150: capillary tube
160: air discharge pipe 200: water tank
300: supply pump 400: bypass pipe
410: bypass solenoid valve 500: control unit

Claims (4)

A wet channel of the evaporative cooler;
A water spray pipe disposed above the wet channel and receiving water from a supply pump;
A capillary tube extending in a predetermined length toward a constant wet channel in a lower region of the water spray pipe to inject water into the wet channel;
A control unit controlling the amount of water supplied from the supply pump to the water injection pipe;
A bypass pipe disposed on the discharge side of the supply pump, and a bypass valve for opening and closing the bypass pipe,
The control unit controls the supply pump to be driven at the maximum rotational speed with the bypass valve closed at the beginning of operation, and opens the bypass valve and reduces the rotational speed of the supply pump when the water spray pipe is full. Pour device, characterized in that.
The method of claim 1,
The water injection pipe is a water injection device, characterized in that the air discharge pipe for discharging the air in the water injection pipe to the outside formed a predetermined length toward the wet channel.
The method according to claim 1 or 2,
Water supply apparatus, characterized in that the heat exchange fin is formed in the inside of the wet channel.
The method of claim 1,
The capillary device further comprises a swing driving part which rotates the water injection pipe to spray water at a predetermined angle on the upper portion of the wet channel.

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