KR101719164B1 - Cool water controlling apparatus - Google Patents

Abstract

The present invention relates to a cold water control device for sufficiently controlling the water intake control (supply / interruption) and the cooling power of the cooling device according to the water level in the cold water tank, thereby sufficiently securing the effective water flow amount.
The cold water control apparatus according to the present invention comprises a cold water tank for receiving purified water to generate cold water, a cooling unit for cooling purified water in the cold water tank, an inlet valve for supplying purified water to the cold water tank, A water level sensing unit for sensing the level of the cold water in the cold water tank; and a controller for controlling the cooling power of the cooling unit to a maximum cooling power when the water level sensed by the water level sensing unit is in the middle water level region, And a water supply step of controlling the water inlet valve to supply the water to the cold water tank for a preset time or a predetermined flow rate after the temperature of the cold water from the temperature sensor reaches a predetermined target temperature or lower And a control unit for performing the operation.

Description

COOL WATER CONTROLLING APPARATUS

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cold water control apparatus, and more particularly, to a cold water control apparatus that sufficiently controls water intake control (supply / interruption) and cooling control of a cooling apparatus according to a water level in a cold water tank .

The water purifier purifies the raw water by using various filters, and then it is heated or cooled by the hot water, the hot water and the cold water to supply to the user. Here, the normal temperature water is usually 15 to 25 ° C, the hot water is 40 to 70 ° C, and the cold water is 4 to 6 ° C. Particularly, for cooling, the water purifier is provided with a cold water tank for storing purified water by using a cooling device and cooling it with cold water.

The conventional water purifier adopts the system in which the user obtains the purified water in the cold water tank as much as the amount of cold water to be dispensed, so that the cold water in the cold water tank is mixed with the purified water, and the temperature of the cold water gradually rises as the amount of cold water is increased. When the cold water is continuously flown, the temperature of the cold water is, for example, 1 cup (4 캜) → 2 cups (4.5 캜) → 3 cups (5 캜) -> 7 cups (9 ℃) → 8 cups (12 ℃) → 9 cups (18 ℃) The water temperature gradually increases. Therefore, there is a problem in that after a certain amount of water outflow, the user can not feel cold water.

In addition, the conventional water purifier can not be installed in a region where the water pressure of the water to be received is low because the water pressure to be discharged varies depending on the water pressure of the cold water outgoing water system, and the internal structure of the cold water tank is constant Due to the structure, it is quite complicated in structure because it has a structure in which a plurality of partitions are installed in the cold water tank to delay the mixing of cold water with purified water in the cold water tank.

The present invention controls the cooling power of the cooling device to prevent the mixing of cold water and purified water by minimizing the change of the cold water temperature, And to provide a cold water control device capable of securing the cold water.

The cold water control apparatus according to the present invention comprises a cold water tank for receiving purified water to generate cold water, a cooling unit for cooling purified water in the cold water tank, a water inlet valve for supplying purified water to the cold water tank, A water temperature sensor for sensing the temperature of the cold water in the cold water tank; a temperature sensor for sensing the temperature of the cold water in the cold water tank; And a controller for controlling the water inlet valve to control the purified water supply flow rate to the cold water tank on the basis of the water level sensed by the water level sensing unit, wherein the water level sensed by the water level sensing unit The control unit controls the cooling power of the cooling unit to a maximum cooling power to perform cooling, and the temperature sensing unit Wherein the controller controls the inlet valve to supply the purified water to the cold water tank for a preset time or a predetermined flow rate after the temperature of the cold water in the hot water tank reaches a predetermined target temperature or lower, When the water level sensed by the sensing unit is in the low water level region, the control unit controls the water inlet valve so that the purified water reaches the full water level of the cold water tank, and regulates the cooling power of the cooling unit to the maximum cooling power.

In addition, when the water level sensed by the water level sensing unit is in the middle water level region, the controller performs the water purifying process until the water level sensed by the water level sensing unit reaches the full water level, When the temperature becomes the predetermined target temperature or less, it is preferable that the purified water supply process is performed again to gradually supply the purified water to the cold water tank.

When the water level sensed by the water level sensing unit is in the middle water level area, the control unit controls the water outlet unit to perform an outflow operation when the water outlet unit obtains an outflow input from the input unit during the water supply process, It is preferable to stop the supply of purified water through the inlet valve.

When the water level sensed by the water level sensing unit is a high water level area, the control unit interrupts the supply of the purified water through the inlet valve, and when the temperature of the cold water is below a predetermined target temperature, And when the temperature of the cold water is higher than the predetermined target temperature, the cooling power of the cooling unit is adjusted to the maximum cooling power.

Preferably, the controller determines whether the water level sensed by the water level sensing unit is in a low water level region after the watering operation is completed.

Also, the cold water control apparatus may include a circulation unit for stirring or circulating the cold water in the cold water tank. After the water level sensed by the water level sensing unit becomes a full water level region in the low water level region, When the temperature of the cold water is lower than the reference circulation temperature, the control unit controls the circulation unit to stir or circulate the cold water.

When the water level sensed by the water level sensing unit is in the middle or high water level region, the control unit may control the water level sensor from the temperature sensing unit, When the temperature of the cold water is higher than the predetermined target temperature, it is preferable to control the circulation unit to stir or circulate the cold water.

According to the present invention, irrigation water is supplied and cut off based on the water level of the cold water irrespective of the amount of water to be dispensed, and the cooling power of the cooling device is controlled to prevent mixing of cold water and purified water, minimize change in cold water temperature, It is possible to secure a sufficient cold water effective water flow rate.

Further, the present invention has an effect that the cold water can be cooled more quickly without a complicated structure such as a partition structure inside the cold water tank.

In addition, the present invention can improve the cooling efficiency while uniformly maintaining the temperature of the cold water by using the circulation device for circulating or leaving the cold water in the cold water tank, and performing the outgoing operation using the circulation device, Even when the water pressure of the cold water control device (water purifier) is low, the cold water control device (water purifier) operates normally.

In the case where the water level of the cold water is in the low water level region, the water is continuously received until reaching the full water level region, and the cooling by the maximum cooling power and the circulation of the cold water are performed, So that the cold water kept at the target temperature can be continuously discharged until the water level of the cold water becomes the low water level (including the detection of the water level), and the additional supply of the purified water is prevented during the continuous water outflow, It is possible to continuously supply the user with the cold water, which is kept substantially constant without any change in the temperature of the water.

According to the present invention, the cold water is gradually supplied to the cold water tank to be filled up to the full water level region by supplying the purified water when the water level of the cold water is higher than the target temperature, So that it is possible to always go out.

According to the present invention, the cold water in the cold water tank is rapidly cooled to the target temperature by the cooling by the cooling part and the circulation of the cold water by the circulation part, and the circulation of the cold water is controlled on the basis of the reference circulation temperature, There is a problem that the durability of the circulation part according to driving is lowered and noise is minimized.

1 is a configuration diagram of a cold water control device.
2 is a schematic cross-sectional view of an embodiment of the cold water tank 30 of FIG.
3 is a control flowchart of the cold water control apparatus of FIG.

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

1 is a configuration diagram of a cold water control device. The cold water control device includes a water inlet valve 10 for supplying water to the cold water tank 30, a flow rate sensing unit 20 for sensing the flow rate of purified water supplied from the water inlet valve 10 to the cold water tank 30, A cold water tank 30 for receiving cold water in the cold water tank 30, a water level sensing unit 40 for sensing a water level in the cold water tank 30, an outflow valve 50 for discharging cold water in the cold water tank 30, A temperature sensing unit 70 for sensing the temperature of the cold water in the cold water tank 30 and a circulation unit for circulating or circulating the cold water in the cold water tank 30 A target temperature setting of the cold water, a target circulation temperature of the cold water, and the like, from the user, And the like), and a control unit (not shown) for controlling the above- It is the water outlet, and a configuration in controller 200 to sufficiently ensure the effective chulsuryang of cold water kept at the target temperature or less by controlling the cooling capacity of the cooling control unit 60. It should be noted that a power source unit (not shown), a water inlet valve 10, a flow rate sensing unit 20, a cold water tank 30, a water outlet valve 50, a temperature sensing unit 70, The description is omitted because it corresponds to a technique which is naturally recognized by a person having ordinary knowledge.

The water level sensing unit 40 is a device for sensing the water level in the cold water tank 30. For example, the water level sensing unit 40 may be a low water level region (or a water level sensing region), a middle water level region, ≪ / RTI > The number of regions is variable and includes two or more regions.

The cooling unit 60 is mounted on the cold water tank 30 and regulates the cooling power under the control of the control unit 200. The cooling unit 60 includes, for example, a thermoelectric element.

The circulation unit 80 is a device for stirring or circulating the cold water so that the cold water in the cold water tank 30 is well mixed with each other, and includes, for example, a stirring device and a circulation pump.

The control unit 200 performs the supply or addition of the purified water based on the water level in the cold water tank 30 and controls the cooling power of the cooling unit 60 based on the water level in the cold water tank 30 and the temperature of the cold water And this control process is described in detail below.

2 is a simplified cross-sectional view of an embodiment of the cold water tank 30 of FIG. 2, the cold water tank 30 includes a water inlet pipe L1 for receiving or receiving purified water, an induction pipe L2 for supplying cold water to the circulation unit 80, a water outlet valve 50, And a circulation pipe L3 having a circulation hole 82 between the circulation units 80. The water outlet valve 50 has a water outlet pipe L4 for discharging cold water supplied through the circulation pipe L3 do.

The water level sensing unit 40 includes a first water level sensing unit 41 for sensing a full water level (c region), a second water level sensing unit 42 for sensing a low water level (a region) or a middle water level (b region) Respectively. The water level sensing unit 40 confirms that the current water level CL is in the high water level according to the sensing signal from the first water level sensing unit 41 and outputs the current water level CL in accordance with the sensing signal from the second water level sensing unit 42 CL is in the middle water level and confirms that the current water level CL is in the low water level according to the undetected signal from the second water level sensing unit 42 and outputs the water level value corresponding to the confirmed water level to the control unit 200 .

The cooling unit 60 is mounted on the side surface of the cold water tank 30 to cool the purified water in the cold water tank 30 and to circulate the circulation unit 80 through the induction pipe L2 in a state in which the water outlet valve 50 is closed The supplied cold water is injected through the circulation hole 82 of the circulation pipe L3 to be stirred or circulated throughout the inside of the cold water tank 30. [ Since the circulating unit 80 forcibly discharges the cold water supplied through the induction pipe L2 through the circulation pipe L3 and the water discharge pipe L4 while the water outlet valve 50 is opened, The cold water control device can be installed.

The cold water tank 30 and the circulation unit 80 of FIG. 2 are merely examples. In the case of the circulation unit 80, the cold water in the cold water tank 30 can be circulated . ≪ / RTI >

3 is a control flowchart of the cold water control apparatus of FIG. In the start step, the control unit 200 performs the cooling control while keeping the water outlet valve 50 in the off state.

In step S1, the control unit 200 determines whether the current water level CL according to the water level value supplied from the water level sensing unit 40 is included in the low water level (a region). If the current water level CL is in the low water level a region, the process proceeds to step S3, otherwise the process proceeds to step S17.

In step S3, the controller 200 controls the inlet valve 10 so that the purified water is received into the cold water tank 30 through the inlet pipe L1.

In step S5, the control unit 200 determines whether the current water level CL according to the water level value supplied from the water level sensing unit 40 is included in the water level (c area). If the current water level CL is the c-level water level, the process proceeds to step S7; otherwise, the process proceeds to step S3 to supply an integer.

In step S7, the control unit 200 controls the water inlet valve 10 to block the intake of purified water.

In step S9, the control unit 200 controls the cooling unit 60 to perform cooling with the maximum cooling power of the cooling unit 60. [

In step S11, the controller 200 determines whether the cold water temperature CT detected by the temperature sensing unit 70 is lower than the reference circulation temperature. If the cold water temperature CT is lower than the reference circulation temperature, the process proceeds to step S13; otherwise, the process proceeds to step S9 to perform cooling. For example, the reference circulation temperature is set such that the cold water in the cold water tank 30 is quickly cooled to the target temperature by the cooling by the cooling unit 60 and the circulation of cold water by the circulation unit 80 (step S13) For example, 10 [deg.] C. In addition, circulation of the cold water is performed from below the reference circulation temperature, so that the durability of the circulation unit 80 due to the continuous driving of the circulation unit 80 is lowered and the noise is minimized.

In step S13, the control unit 200 operates the circulation unit 80 to stir or circulate the cold water in the cold water tank 30. In addition, the control unit 200 may intermittently perform the circulation operation by the circulation unit 80 to improve the cooling effect of the cold water. For example, the control unit 200 operates the circulation unit 80 for a reference operation time (for example, two minutes) and controls the operation of the circulation unit 80 for a reference stop time (for example, two minutes) Thereby maximizing the cooling effect of cold water.

In step S15, the controller 200 determines whether the cold water temperature CT sensed by the temperature sensing unit 70 is equal to or lower than the target temperature of the predetermined cold water lower than the reference circulation temperature. If the cold water temperature CT is equal to or lower than the target temperature, the process proceeds to step S37; otherwise, the process proceeds to step S13, and the cold water cycle is performed.

In step S17, the control unit 200 determines whether the current water level CL according to the water level value supplied from the water level sensing unit 40 is included in the middle water level (area b). If the current water level CL is in the middle water level b region, the process proceeds to step S19; otherwise, the process proceeds to step S31.

In step S19, the control unit 200 controls the cooling unit 60 to perform cooling with the maximum cooling power of the cooling unit 60. [

In step S21, the controller 200 determines whether the cold water temperature CT sensed by the temperature sensing unit 70 is equal to or lower than the target temperature of the predetermined cold water. If the cold water temperature CT is equal to or lower than the target temperature, the process proceeds to step S25; otherwise, the process proceeds to step S23.

In step S23, the control unit 200 operates the circulation unit 80 to stir or circulate the cold water in the cold water tank 30.

In step S25, the control unit 200 controls the inlet valve 10 to acquire the constant for a predetermined time (for example, 5 seconds) using the built-in timer, (For example, 150 cc) using a predetermined flow rate. The predetermined time and the predetermined flow rate can be variably set.

In step S27, the control unit 200 controls the water inlet valve 10 to cut off the supply of purified water.

In step S29, the control unit 200 determines whether the current water level CL according to the water level value supplied from the water level sensing unit 40 is included in the water level (c area). If the current water level CL is the c water level, the process proceeds to step S33, and if not, the process proceeds to step S19.

In step S31, the control unit 200 controls the water inlet valve 10 to cut off the supply of purified water. However, if supply of the current constant is interrupted, the control unit 200 proceeds to step S33 without performing step S31.

In step S33, the controller 200 determines whether the cold water temperature CT sensed by the temperature sensing unit 70 is equal to or lower than the target temperature of the predetermined cold water. If the cold water temperature CT is equal to or lower than the target temperature, the process proceeds to step S37; otherwise, the process proceeds to step S35.

In step S35, the control unit 200 controls the cooling unit 60 to perform cooling with the maximum cooling power of the cooling unit 60. [

In step S37, the control unit 200 operates the circulation unit 80 to stir or circulate the cold water in the cold water tank 30.

In step S39, the control unit 200 controls the cooling unit 60 to perform cooling with a cooling power lower than the minimum cooling power or the maximum cooling power of the cooling unit 60. [

In the above-described steps S1 to S7, the controller 200 successively acquires the constant until the water level of the low water level a reaches the high water level c region, and in steps S9 to S15, Cooling by cold power and circulation of cold water are carried out, so that effective water amount of cold water corresponding to the high water level c region is quickly secured. Further, in the present invention, when the water level CL is in the high water level or the middle water level area, it is possible to continuously discharge the cold water maintained at the target temperature until the water level of the cold water becomes the low water level So that additional supply of purified water is prevented during the outgoing watering. Accordingly, the cold water control apparatus according to the present invention is capable of controlling the temperature of the cold water, for example, from one glass (4 ° C) to two glasses (4 ° C) to three glasses (4 ° C) It is possible to continuously supply the user with cold water in which the temperature of the one to eight cups (4 캜) is kept constant without changing the temperature of the cold water.

In the above-described steps (S17) to (S29), the controller 200 supplies the constant for a preset time or a predetermined flow rate while cooling the water level to the high water level c region to increase the flow rate of the cold water gradually To < / RTI > In this process, after the coolant temperature CT of the supplied purified water reaches the target temperature, the controller 200 causes the supply of additional purified water to be performed so that the cold water temperature increases the flow rate of the cold water while maintaining the target temperature . For example, the controller 200 supplies the integer for a predetermined time (for example, 5 seconds) in step S25, and if the current water level CL does not reach the water level c area, ), (S21), and (S23) to perform the step S25 again after the cold water is cooled to the target temperature or lower, thereby gradually increasing the flow rate of the cold water in the cold water tank 30. As another example, the controller 200 supplies an integer for a predetermined flow amount (for example, 150 cc) in step S25, and if the current water level CL does not reach the c-area where the water level is high, (S21), and (S23) to perform the step S25 again after the cold water is cooled to the target temperature or lower, thereby gradually increasing the flow rate of the cold water in the cold water tank 30. [ That is, according to the present invention, when the water level sensing unit 40 senses the b region having a heavy water level, the water is gradually supplied to the cold water tank 30 so that the cold water is filled up to the water level c, Cold water can always be dispatched.

The control unit 200 controls the cooling power of the cooling unit 60 based on the cold water temperature CT in the cold water tank 30 which is the water level of the high water level c region in the above described steps S31 to S39, Thereby keeping the temperature CT below the target temperature.

If the water level CL is in the middle water level b region or the high water level c region while the water level is being inputted from the input unit 100, the controller 200 controls the water outlet valve 50 (S1) when there is no additional watering operation for a certain period of time (for example, one minute) after the watering operation is completed, or after the watering operation is completed, ) To perform a cold water control process. However, when the current operation is a cooling operation as in steps S19, S35, and S39 during the outgoing operation, the controller 200 continuously performs the cooling operation, (S25), the supply of purified water is stopped to prevent mixing of purified water and cold water.

In the foregoing, the present invention has been described in detail by way of examples on the basis of the embodiments of the present invention and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

10: incoming valve 20: flow rate sensing unit
30: cold water tank 40: water level sensing unit
50: water outlet valve 60: cooling section
70: temperature sensing unit 80: circulation unit
90: display portion 100: input portion
200:

Claims (7)

A cold water tank for supplying purified water to generate cold water;
A cooling unit for cooling purified water in the cold water tank;
An inlet valve for supplying purified water to the cold water tank;
An outflow section for leaving the cold water generated in the cold water tank;
An input unit for obtaining an outflow input for the cold water generated in the cold water tank;
A temperature sensing unit sensing the temperature of the cold water in the cold water tank;
A water level sensing unit for sensing a water level of the cold water in the cold water tank;
And a controller for controlling the water inlet valve to control the purified water supply flow rate to the cold water tank on the basis of the water level sensed by the water level sensing unit,
Wherein the control unit controls the cooling power of the cooling unit to a maximum cooling power to perform cooling, and when the temperature of the cold water from the temperature sensing unit is lower than a predetermined target temperature The water supply valve is controlled to perform a constant supply process for supplying the constant to the cold water tank for a preset time or a predetermined flow rate,
Wherein the control unit controls the inlet valve so that the purified water reaches the full water level of the cold water tank and adjusts the cooling power of the cooling unit to the maximum cooling power when the level sensed by the water level sensing unit is a low- The cold water control device.
The method according to claim 1,
The control unit controls the temperature of the cold water until the water level sensed by the water level sensing unit reaches the full water level after the water purifying process is performed, Wherein the controller further performs the purified water supply process and gradually supplies the purified water to the cold water tank when the temperature reaches the preset target temperature. The method according to claim 1,
When the water level sensed by the water level sensing unit is in the middle water level region, the control unit controls the water outlet to perform an outflow operation when the water outlet is acquired from the input unit during the water supply process, And stops the supply of purified water through the inlet valve.
The method according to claim 1,
The control unit interrupts the supply of the purified water through the inlet valve, and when the temperature of the cold water is lower than a predetermined target temperature, the controller controls the cooling power of the cooling unit to the minimum cooling power And controls the cooling power of the cooling unit to a maximum cooling power when the temperature of the cold water is higher than a predetermined target temperature. The method of claim 3,
Wherein the control unit determines whether the water level sensed by the water level sensing unit is in the low water level region after the watering operation is completed.
The method according to claim 1,
The cold water control apparatus includes a circulation unit for stirring or circulating cold water in the cold water tank. After the water level sensed by the water level sensing unit becomes a full water level region in the low water level region, Wherein when the temperature is lower than the reference circulation temperature, the control unit controls the circulation unit to stir or circulate the cold water.
The method according to any one of claims 1 to 5,
Wherein the control unit controls the temperature of the cold water in the cold water tank to a predetermined value when the water level sensed by the water level sensing unit is in the middle or high water level region, Wherein the control unit controls the circulation unit to stir or circulate the cold water if the temperature of the cold water is higher than the predetermined target temperature.

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