KR100620579B1 - Control method of purifier - Google Patents

Abstract

The present invention relates to a water purifier control method, and more particularly, to a water purifier control method for maintaining the water purifier in a state similar to the initialization of the water purifier when the water purifier is not used for a long time.

Water purifier initialization, standby state, flow path change motor, refrigerant water supply

Description

Control method of purifier

1 is a block diagram of a water purifier according to a preferred embodiment of the present invention.

2 is a flowchart of a water purifier control method according to a preferred embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

220: filter 340: electrolytic cell solenoid valve

400: electrolytic cell 501: refrigerant tank

502: refrigerant coil 520: hot water tank assembly

540: hot water safety solenoid valve 560: alkali cold water pipe

580: alkali hot water pipe 620: coke

970 pressure switch 980 alkali water pipe

800: drain solenoid valve 900: acidic water solenoid valve

910: refrigerant tank solenoid valve 930: refrigerant tank

940: cold water solenoid valve 950: normal temperature solenoid valve

960: hot water solenoid valve 990: room temperature water pipe

The present invention relates to a water purifier control method, and more particularly, to a water purifier control method for maintaining the water purifier in a state similar to the initialization of the water purifier when the water purifier is not used for a long time.

Due to the recent environmental problems such as water quality, air, and soil caused by the recent industrial development, general households and offices purify the water by the filter as a means to provide clean drinking water, and thus select the purified water. Cooling or heating according to the cold, hot water to be supplied to the hot water is a situation that is widely used.

It is a method of exiting and stopping after judging on / off by a key input of an existing water purifier, or of exiting and stopping by a user sensing method using a human body sensor.

As a water purifier control method, it is proposed in the publication of Korean Utility Model No. 327034.

However, the conventional water purifier control method is inefficient in detecting the human body because the sensing performance of the human body sensor varies according to the user's movement, direction of movement, speed, and the like.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a water purifier control method for maintaining a water purifier in a state similar to initialization of a water purifier when the water purifier is not used for a long time.

The water purifier control method of the present invention for achieving the above object is a detection step of detecting whether the water purifier is discharged, and if it is determined that the water is out, switch to the water extraction mode, and if it is determined that the water exit is determined whether the water stop is maintained for a certain time And a standby step of switching each operating device of the water purifier to a standby state when the water extraction stop is maintained.

According to this configuration, when the water purifier is in the water discharge stop state for a predetermined time, there is an advantage that the water purifier automatically enters the standby mode.

In addition, the system can be stabilized by changing the flow path change motor, the refrigerant tank, the hot water tank and the filter to the standby state similar to the initial state in the standby mode.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

1 is a block diagram of a water purifier according to a preferred embodiment of the present invention.

As shown in FIG. 1, the water purifier according to the present embodiment includes a filter 220 that largely filters and purifies raw water, a solenoid valve that controls the flow of purified water passing through the filter 220, and the solenoid valve. It consists of a coke 620 to the water is discharged, a pressure switch 970 disposed in the flow path between the solenoid valve and the cock 620, and a control unit for sending a signal of the pressure switch 970 to the solenoid valve.

Detailed description of the configuration overlapping with the conventional ionizer will be omitted.

When the voltage is applied to the electrode of the electrolytic cell 400 for a predetermined time or more in order to withdraw the ionized water, the scale is fixed to the electrode plate and requires automatic cleaning. To this end, the electrolytic cell 400 may be provided with a flow path changing motor for changing the flow path to the phase angle of 180 degrees in the outlet pipe connected to each chamber.

The driving method for the flow path changing motor is referred to Korean Patent Laid-Open Publication No. 2004-0108296, and a detailed description thereof will be omitted.

Furthermore, it is preferable that the coolant tank assembly is provided to cool the alkaline ionized water generated from the electrolytic cell 400 to provide alkali cold water.

 In the coolant tank assembly, an alkali cold water pipe 560 containing alkali water is passed through the coolant tank 501, and the coolant coil 502 for cooling the water inserted into the coolant tank 501 in the coolant tank 501. Is inserted. Both ends of the refrigerant coil 502 is connected to the cooling means.

Here, the water inserted into the refrigerant tank 501 is supplied to the water through the refrigerant tank tube 930 when the refrigerant tank water supply solenoid valve 910 is opened.

Thus, the alkaline water in the alkali cold water pipe 560 passing through the refrigerant tank 501 is cooled.

Alkaline normal temperature water generated in the electrolytic cell 400, the flow is controlled by an alkaline water supply solenoid valve installed after the electrolytic cell 400, the alkali normal temperature water is refrigerant through the alkali cold water pipe 560 when the cold water solenoid valve 940 is opened. It is transferred to the bath assembly, cooled, and discharged.

Alkaline normal temperature and normal temperature purified water formed in the electrolytic cell 400 is controlled by the normal temperature solenoid valve 950.

The room temperature water pipe 990 which transfers the room temperature water is joined between the pressure switch 970 and the refrigerant water tank assembly, thereby providing alkali room temperature water, alkali cold water, and room temperature constant water through one coke 620.

In addition, a hot water tank assembly 520 for heating and storing the alkaline ionized water generated from the electrolytic cell 400 may be provided to provide alkaline hot water.

The alkaline room temperature water is transferred through the alkali hot water pipe 580 and then warmed in the hot water tank assembly 520 and then stored and discharged into the alkaline hot water.

Solenoid valves for controlling the flow of purified water may be further provided on each flow path in order to selectively and efficiently withdraw each functional water.

In addition, the cock 620 is provided to the water can be withdrawn.

The pressure switch 970 may be installed after the point where the room temperature water pipe 990 joins, and may be installed in the alkaline water pipe 980 through which the alkali room temperature water and the room temperature purified water and the alkaline cold water are transferred.

 In addition, a control unit (not shown) for transmitting a signal of the pressure switch 970 to the solenoid valve is provided.

The pressure switch 970 is preferably a low pressure cutoff switch.

For a specific operating mechanism for the low pressure cut-off switch, reference is made to the publication of No. 20-0294986, and only the characteristic effects of the present invention will be described.

The low pressure shutoff switch switches using the low pressure of the liquid, and more specifically, the low pressure shutoff switch by controlling the flow-related device such as the solenoid valve by operating the switch using the pressure of the flowing liquid installed in the middle of the liquid flow. It automatically adjusts the flow of liquid according to the pressure set in.

When the user presses the button of the desired number of functions, the control unit waits for on / off of the solenoid valve concerned.

At this time, when the coke 620 is opened and the pressure in the pipe is lowered, a signal is input to the pressure switch 970 and the signal is transmitted to the related solenoid in the waiting state, and the function water is discharged while opening the solenoid.

On the other hand, when the coke 620 is closed and a high pressure is sensed and the signal of the pressure switch 970 is cut off, the related solenoid valve which is open is closed and supply of the functional water is stopped.

In this way, the water purifier opens and closes the solenoid valve associated with each functional water as the coke 620 is opened and closed, so that the functional water is immediately generated and discharged when necessary.

The operation of this embodiment having the above-described configuration will be described below.

2 is a flowchart of a water purifier control method according to a preferred embodiment of the present invention.

As shown in FIG. 2, the water purifier control method includes a sensing step of detecting whether the water purifier is discharged, and when it is determined that the water is discharged, switch to the water extraction mode, and when it is determined that the water is stopped, determining whether the water discharge is maintained for a predetermined time. And a standby step of switching each operating device of the water purifier to a standby state if the water extraction stop is maintained.

Whether or not the water purifier is installed at the front end of the cock 620 is determined to be in the outflow state in the case of low pressure through the value input from the pressure switch 970 for detecting the pressure, and in the case of high pressure, the outlet of the water purifier is taken out.

Alternatively, it is possible to determine whether the water purifier is discharged through a lever or a user's key input.

If it is determined that the water is discharged, the water purifier is switched to the water extraction mode.

If it is determined that the withdrawal stops, it is determined whether the withdrawal stops for a certain time.

If no water is discharged from the water purifier for a certain time, a waiting step is performed to switch each operating device of the water purifier to a standby state.

Meanwhile, the method may further include initializing the standby state data before switching each operating device to the standby state.

Each operation device may be a flow path change motor, a refrigerant tank 501, a hot water tank, a filter 220, or the like.

The refrigerant tank 501 opens the refrigerant water drain solenoid valve installed in the drain line connected to the refrigerant tank 501 to automatically clean the refrigerant tank 501.

The filter 220 is flushed to be atmospheric, and the flushing of the filter 220 is an operation of washing the filter 220. The filter 220 includes a separate flow path, a valve, a pump, and the like in the filter 220. Drain the water and supply the clean water to the filter 220 again.

Since the flushing of the filter 220 is presented in Korean Utility Model Model No. 1999-0027394, a detailed description thereof will be omitted.

The flow path changing motor (not shown) causes the phase angle to be at 0 or 180 degrees to complete the flow path change, thereby making it atmospheric.

Detects the water level of the coolant tank 501 basically provided in the water purifier and opens the coolant tank water supply solenoid valve 910 in the coolant tank 501 so that the proper water level becomes below the proper water level. Do

It is preferable that the proper water level be a high water level.

Sensing the water level in the hot water tank may further include the step of supplying water to the appropriate level.

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

According to the water purifier control method of the present invention as described above has the following advantages.

When the water purifier is in the discharge stop state for a certain time, there is an advantage to automatically enter the water purifier.

In addition, the system can be stabilized by changing the flow path change motor, the refrigerant tank, the hot water tank, and the filter to the standby state similar to the initial state in the standby mode.

Claims (7)

A sensing step of detecting whether the water purifier is discharged; Switching to the exit mode when determined to exit, and determining whether to stop exiting for a predetermined time when determined to stop exiting; A water purifier control method comprising the step of converting each operating device of the water purifier to the standby state when the water discharge is maintained. The method of claim 1, The sensing step is characterized in that the water purifier control method for detecting through the input value of the pressure switch for detecting the hydrostatic pressure of the front end of the cock. The method according to claim 1 or 2, The atmospheric step is a water purifier control method comprising the refrigerant tank atmospheric step of washing the refrigerant tank. The method according to claim 1 or 2, The air purifying step includes a filter air purifying step of flushing the filter. The method according to claim 1 or 2, The air purifying step includes the water purifying step of the flow path change motor to complete the operation of the flow path change motor. The method according to claim 1 or 2, The atmospheric control step is a water purifier control method comprising the refrigerant tank atmospheric step of completing the water supply to the refrigerant tank. The method according to claim 1 or 2, The atmospheric step is a water purifier control method comprising the hot water tank atmospheric step of completing the water supply to the hot water tank.

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