KR20110007417A - Controlling method for cooling water container mixer motor - Google Patents

Abstract

PURPOSE: A method for controlling a cool-water container stirring motor is provided to improve cooling performance in a cool-water providing process by increasing the heat exchange amount of purified-water and cool-water through a cooling coil. CONSTITUTION: The rotation speed of a cool-water container stirring motor is controlled(S10). The temperature of cool-water contained in a cool-water container is measured using a temperature sensor(S11). The measured temperature is compared with first temperature. An compressor and the stirring motor are turned on(S12). The measured temperature is compared with second temperature which is lower than the first temperature(S13). The compressor is turned off(S14). After about 5minutes, the stirring motor is turned off(S15).

Description

Controlling method for cooling water container mixer motor

The present invention relates to a control method of a cold water tank stirrer motor capable of differently controlling the rotation of a stirrer motor in a process of freezing ice around an evaporator (cooling operation) and a process of extracting cold water (cold water extraction operation).

1 is a perspective view of the cold water heater 100 shown to show the evaporator 130, the cold water coil 140, etc. accommodated inside the cold water tank 110, Figure 2 is a convenience evaporator 130 in Figure 1, Cold water coil 140, the bracket 150 is a perspective view of the cold ion water heater 100 is omitted.

1 to 2, the cold ion water heater 100, the cold water tank 110 is filled with the cooling water inside the receiving portion is formed, the inside of the cold water tank 110 and a separate compressor and An evaporator 130 connected to the heat exchanger by a refrigeration cycle, a cold water coil 140 which is surrounded by the outside of the evaporator 130 and heat-exchanges with the evaporator 130 so that the purified water passes through the purified water, and The cold water tank cover 120 and the cold water tank cover 120 which are fastened to the upper surface of the cold water tank 110 while the evaporator 130 and the cold water coil 140 are accommodated in the cold water tank 110. It is configured to include a stirrer motor 160 is installed on the upper surface of the stirrer fan 170 is fixed to the rotating shaft of the stirrer motor 160 is rotated so as not to freeze the coolant contained in the cold water tank 110.

In addition, the cold ion water heater 100 is mounted between the cold water tank 110 and the cold water tank cover 120, the evaporator 130 and the cold water coil 140 accommodated in the cold water tank 110, It is configured to include a bracket 150 for supporting.

On the other hand, the cold ion water heater 100, the water level sensor 190 for detecting the level of the cooling water filled in the cold water tank 110, and further comprises a temperature sensor 180 for detecting the temperature of the cooling water.

In order to operate the cold ion water heater 100 by such a configuration, first, the cooling water tank 110 is filled with appropriate cooling water using the water level sensor 190.

When the appropriate amount of cooling water is filled, the refrigerant formed by operating a compressor (not shown) is sent to the evaporator 130 to form ice around the refrigerant.

Here, just freezing the ice produces ice that is full of white air, not clear, hard ice.

These ice are less dense and have relatively less latent heat.

Accordingly, in order to form a dense, clear and hard ice, it is preferable to form a flow in the cooling water. At this time, the stirrer fan 170 is rotated by operating the stirrer motor 160.

As such, when the flow occurs in the cooling water, the ice around the evaporator 130 is formed clear and hard.

At this time, the temperature of the evaporator is 0 ° C. when it is in frozen water, but goes below freezing when it is surrounded by ice.

When the temperature sensor 180 detects that the coolant filled in the cold water tank 110 has reached an appropriate temperature (less than -1 ° C), a separate controller (not shown) determines that an appropriate amount of ice is frozen in the coolant. Thus, the compressor is stopped and the stirrer fan 170 rotated by the stirrer motor 160 is also stopped.

Then, when the consumer withdraws the cold water, the purified water supplied from the purified water supply unit passes through the cold water coil 140, the purified water is heat exchanged with the cooling water reached the appropriate temperature in the process of passing through the cold water coil 140 Is lowered and discharged as cold water from the purified water extraction unit.

Here, in order to actively exchange heat between the purified water passing through the cold water coil 140 and the cooling water reaching the appropriate temperature, the flow is formed in the cooling water by rotating the stirrer fan 170 connected to the stirrer motor 160.

In this process, the heat exchange amount of the purified water and the coolant is increased, and the temperature of the coolant to heat exchange with the purified water is dissolved to melt the ice formed around the evaporator 130, and the temperature of the coolant is maintained at 0 ° C. do.

At this time, in order to improve performance (increase in the amount of heat exchange), by rapidly rotating the stirrer motor 160, the cooling water may be strongly stirred by the stirrer fan 170 connected to the rotating shaft of the stirrer motor 160.

However, the faster the rotation of the stirrer fan 170, the faster the rotation of the cooling water, the vortex phenomenon occurs, so that the 'rustling' water sound (noise) is generated.

These noises also occur at the same time when the compressor is running.

As described above, the conventional cold ion water heater 100 controls the stirrer motor 160 at one rotation speed, and the rotation speed of the stirrer motor 160 is set to a maximum RPM (revolutions per minute) without noise. Since there is a problem that the cooling performance is limited to satisfy the noise performance.

The present invention by controlling the rotation of the stirrer motor in the process of freezing the ice around the evaporator (cooling operation) and the cold water withdrawal process (cold water extraction operation), respectively, to increase the cooling performance during cold water extraction and noise during the cooling operation It is an object of the present invention to provide a control method of a cold water tank stirrer motor which can reduce the amount of water.

A control method of a cold water tank stirrer motor of the present invention for achieving the above object, the first control step of controlling the rotational speed of the cold water tank stirrer motor; And a second control step of controlling the rotational speed of the agitator motor, unlike the rotational speed of the agitator motor controlled in the first control step, depending on whether the cold water output signal is turned on or off.

In addition, in the control method of the cold water tank stirrer motor of the present invention, the second control step includes a determination step of determining whether the cold water export signal is ON / OFF, when the cold water export signal is ON, the second The rotation speed of the stirrer motor controlled in the control step is controlled to be faster than the rotation speed of the stirrer motor rotated in the first control step.

Further, in the control method of the cold water tank stirrer motor of the present invention, when the cold water output signal is OFF, the rotation speed of the stirrer motor is decelerated and stopped.

As described above, the control method of the cold water tank stirrer motor of the present invention has the following advantages.

1) Since the present invention can control the rotational speed of the stirrer motor differently according to the operating state, it is possible to achieve the cooling performance and the noise performance, respectively, suitable for the operating state. In other words, in the cooling operation, the rotational speed is controlled at a RPM lower than the maximum RPM that can achieve low noise in the prior art. It can improve performance.

2) When the cold water output signal is turned ON, the stirrer fan whose rotation speed is faster than the rotation speed of the stirrer fan during the cooling operation rotates (cools) the coolant that has cooled after the cooling operation. As the heat exchange amount of is increased, the user can withdraw the cold water having the improved cooling performance.

3) When the cold water export signal is OFF, the rotation speed of the stirrer motor, which was rapidly rotated when the cold water export signal is ON, is decelerated and stopped. Therefore, the noise generated as the stirrer motor rotates in the standby operation mode reduces the noise. I can drive.

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

3 is a flow chart illustrating a process of freezing ice around an evaporator in a control method of a cold water tank stirrer motor according to the present invention.

4 is a flow chart illustrating a process (cold water extraction operation) of extracting cold water from the control method of the cold water tank stirrer motor according to the present invention.

As shown in Figure 3 to 4, the control method of the cold water tank stirrer motor according to the present invention, the first control step (S10) for controlling the rotational speed of the cold water tank stirrer motor 160, and the cold water export signal According to the on / off status (S21) (S23), different from the rotation speed of the stirrer motor 160 controlled in the first control step (S10), the second control for controlling the rotation speed of the stirrer motor 160 Step S20 is included.

The first control step (S10) is a step of controlling the rotational speed of the cold water tank stirrer motor 160 when the process of freezing the ice around the evaporator (cooling operation), that is, before the cold water is discharged.

On the other hand, the second control step (S20) is a step of controlling the rotational speed of the cold water tank stirrer motor 160 when the cold water is discharged (cold water operation), that is, when the user withdraws the cold water.

According to this configuration, since the rotation of the stirrer motor 160 can be controlled differently in the process of freezing the ice around the evaporator (cooling operation) and the cold water withdrawal (cold water extraction operation), the noise during the cooling operation It can reduce and increase cooling performance when cold water is exported.

As shown in FIG. 3, the first control step S10 includes a temperature judging step S11 and S13 for determining a temperature of the cooling water in the cold water tank 110, wherein the temperature judging step S11 is performed. When the temperature determined in S13 is greater than the first temperature (S11), the compressor and the agitator motor 160 are turned on, and when the temperature is smaller than the second temperature smaller than the first temperature (S13), the compressor is turned off and then the agitator motor is turned off. Turn off (160).

In the temperature determination step S11, the temperature of the cooling water is measured using the temperature sensor 180.

That is, when the temperature measured by the temperature sensor 180 is greater than 1 ° C., which is the first temperature (S11), the compressor and the stirrer motor 160 are turned on (S12), and the temperature measured by the temperature sensor 180 is When the temperature is less than -1 ° C, which is a second temperature lower than the first temperature (S13), the compressor is turned off (S14), and after about 5 minutes, the agitator motor 160 is turned off (S15).

At this time, the rotation speed of the stirrer motor 160 rotated in the cooling operation (S10) is preferably 650 RPM.

As shown in FIG. 4, the cold water export operation S20 includes a determination step S21 (S23) of determining whether the cold water export signal is on or off, and when the cold export signal is turned on (S21). ), The rotation speed of the stirrer motor 160 controlled in the second control step S20 is controlled faster than the rotation speed of the stirrer motor 160 rotated in the first control step S10.

That is, in the cold water export operation (S20), when it is determined that the cold water export signal is turned on by a separate control unit (S21), the rotation speed of the stirrer motor 160 is rotated in the first control step (S10) It rotates at 1100 RPM faster than the rotation speed of 650 RPM (160) (S22) to discharge cold water.

Therefore, when the cold water output signal is turned on (S21), since the stirrer fan 170 connected to the rotating shaft of the stirrer motor 160 rotates (cools) the coolant cooled in the first control step (S10), the cold water coil The heat exchange amount between the purified water passing through the 140 and the cooling water is increased, so that the user can withdraw the cold water having high cooling performance.

At this time, in the second control step (S20), when the cold water export signal is OFF (S23), the rotational speed of the stirrer motor 160 is decelerated and stopped.

That is, in the second control step (S20), when it is determined that the cold water export signal is OFF in a separate control unit (S23), the stirrer motor is rotated when the cold water export signal is turned on the rotational speed of the stirrer motor 160 The rotation speed is changed to 650 RPM slower than 1100 RPM, which is the rotation speed of 160 (S24), and after about 10 seconds, the stirrer motor 160 is stopped (S25).

According to this configuration, when the cold water export signal is OFF (S23), since the rotation speed of the stirrer motor 160, which was rapidly rotated when the cold water export signal is in the ON state (S21), is decelerated and stopped, the stirrer is in the standby operation state. As the motor 160 rotates, noise generated as a result of quiet operation may be reduced.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or changes to the present invention without departing from the spirit and scope of the invention described in the claims below It can be modified.

The present invention is suitable to be used to increase the cooling performance in the cold water heater and to reduce the noise during standby operation to enable quiet operation.

1 and 2 are a perspective view of the cold water heater.

3 is a flow chart illustrating a process of freezing ice around an evaporator in a control method of a cold water tank stirrer motor according to the present invention.

Figure 4 is a flow chart showing a process (cold water extraction operation) of the cold water withdrawal, the control method of the cold water tank stirrer motor according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: cold ion water heater 110: cold water tank 120: cold water tank cover

130: evaporator 140: cold water coil 150: bracket

160: stirrer motor 170: stirrer fan 180: temperature sensor

190: water level sensor

Claims (3)

A first control step of controlling the rotational speed of the cold water tank stirrer motor; The control method of the cold water tank stirrer motor including a second control step of controlling the rotational speed of the stirrer motor, different from the rotational speed of the stirrer motor controlled in the first control step, depending on whether the cold water output signal is ON / OFF. . The method of claim 1, The second control step, Determination step of determining whether the cold water export signal ON / OFF, And the rotation speed of the stirrer motor controlled in the second control step is controlled faster than the rotation speed of the stirrer motor rotated in the first control step when the cold water output signal is turned on. 3. The method of claim 2, When the cold water export signal is OFF, the rotational speed of the stirrer motor is decelerated and then stopped.

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