KR20170092076A - water purifier and a control method of the same - Google Patents

Abstract

The present invention relates to a water purifier and, more specifically, relates to a water purifier with improved user convenience. According to an embodiment of the present invention, a direct water purifier for discharging at least one among purified water, cold water and hot water by using the water pressure of an external water supply source comprises: a filter for filtering raw water to generate purified water; a tank for storing the purified water; a water supply passage provided between the filter and the tank to supply the purified water to the tank; a cork for discharging the purified water in the tank; a water discharge passage for supplying the purified water in the tank to the cork; an exhaust passage branched from the water discharge passage; and a check valve provided in the exhaust passage and opened at a pressure lower than the water pressure of the external water supply source to exhaust air in the tank. As a result, the present invention can effectively eliminate noise and water splash generated as the air is discharged into the cork.

Description

Water purifier and control method thereof

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a water purifier, and more particularly, to a water purifier with enhanced user convenience.

The drinking water supply device is a device for supplying drinking water to be consumed by a user. This drinking water supply device may be a unique device, or it may be a part of another device.

For example, a water purifier is a device that passes raw water supplied from an external water source into separate filtration means and then supplies the purified water to the user by filtering. In addition, a device that supplies purified water to cold water or hot water when necessary is also referred to as a water purifier. The water purifier may be a device independent of other appliances.

On the other hand, such a drinking water supply device may form part of a household appliance such as a refrigerator. That is, water purified from the inside of the refrigerator through the water purification device can be supplied to the outside through the drinking water supply device. Of course, water purified in the refrigerator may be cooled or frozen so that cold water or ice may be supplied to the outside through the drinking water supply device.

Therefore, a device that filters raw water and supplies purified water, whether it is an independent device or a non-independent device, can be referred to as a water purifier.

Channels are formed inside the water purifier. In other words, flow paths are provided between the external water supply source and the cocks to which the purified water flows. These channels are spaces filled with raw water or purified water. These channels may include tanks filled with constants.

The flow path may be filled with air for various reasons. Such air can prevent smooth flow of raw water or purified water from the flow path. In addition, this air can be discharged with purified water when it is discharged through the cock. Therefore, there is a possibility that water is splashed on the hand of the user, not the cup or the container for receiving the purified water, and noise may be generated. Particularly, when the purified water is hot water, a safety accident may occur.

Korean Patent Application No. KR10-2011-0076044 (hereinafter referred to as "prior invention") discloses a check valve for discharging air in a tank. The check valve is driven by a mechanical operating pressure and discloses discharging the air inside the tank to the outside only by an increased internal pressure in the tank.

If the internal pressure increases due to the air inside the tank, the purified water may not flow smoothly into the tank. Therefore, it can be said that the check valve is installed in the tank to discharge the air inside the tank to lower the pressure.

In this case, depending on the operating pressure of the check valve, the air inside the tank may not be completely discharged. Therefore, in this case, the operating pressure of the check valve (i.e., the pressure for opening the check valve) can be referred to as the pressure inside the tank. That is, the check valve can be automatically opened when the pressure inside the tank is equal to or higher than a predetermined pressure.

However, it is difficult to optimize the operating pressure of the check valve, and the actual operating pressure varies as the use period elapses. Therefore, there is a problem that effective air discharge is difficult.

The above-mentioned prior art discloses a low water type water purifier for storing water in a tank and then leaving the tank. Therefore, it is not easy to apply this prior art to a water purifier. This is because the inside of the tank of the direct water purifier is pressurized by the water pressure of the external water supply. In this case, when the operating pressure of the check valve is made larger than the water pressure of the external water supply, the check valve is generally not opened. When the operating pressure of the check valve is made smaller than the water pressure of the external water supply, the check valve is opened and the water may be discharged from time to time through the check valve.

On the other hand, the necessity of discharging the air in the tank is also required for the water purifier as well as the water purifier.

Therefore, there is a need to provide a water purifier or a control method thereof capable of effectively discharging the air in the tank in the direct water purifier.

The problem of the conventional water purifier described above is solved through the present invention.

According to one embodiment of the present invention, there is provided a water purifier capable of substantially exhausting air in a tank.

It is an object of the present invention to provide a water purifier capable of lowering the influence of the operating pressure of the check valve on air discharge.

According to an embodiment of the present invention, there is provided a water purifier that can be introduced into the flow path from the outside of the water purifier or can automatically discharge the air generated in the flow path during use of the water purifier. Through this, it is intended to provide a water purifier that can effectively prevent noise and water generated by the outflow of air with purified water.

It is an object of the present invention to provide a water purifier and method of controlling the water purifier that can minimize the addition of a complicated structure or structure and can easily remove air in a method.

According to an embodiment of the present invention, there is provided a water purifier and its control method capable of minimizing the occurrence of water leakage in the water line inside the water purifier by minimizing a pressure rise value and a pressure rise time which are pressurized in the water line in the water purifier.

According to an aspect of the present invention, there is provided a water purifier for discharging at least one of purified water, cold water, and hot water using a water pressure of an external water source itself, / RTI > A tank for receiving purified water; A water supply passage provided between the filter and the tank to supply purified water to the tank; A coke for leaving out the purified water in the tank; An outflow channel for supplying purified water in the tank to the cock; An exhaust passage branching from the outflow channel; And a check valve provided in the exhaust passage and being opened at a pressure lower than the water pressure of the external water source to exhaust air in the tank.

Preferably, the tank is a sealed tank in which the external water source is pressurized to an internal pressure by water pressure.

Preferably, the tank is a hot water tank for heating the purified water. Of course, it may be a cold water tank for cooling cold water. However, the possibility of air generation in the tank and the amount of air accumulation

Preferably, the outflow channel is connected so as to communicate with the uppermost portion of the tank. This is because the air in the tank is accumulated in the upper part, and therefore, the air in the tank is discharged before the purified water.

And the water supply channel is connected to be communicated with the lowermost part of the tank. Through this, smooth flow of water or air can be generated before and after the tank, so that the air can be effectively discharged first.

A water supply valve opened to supply said raw water to said filter; And an outlet valve in which the purified water is opened for leaving the cock.

And a controller for controlling the air supply valve to be opened and the water outlet valve to be closed so that the air is exhausted through the check valve.

The controller may control the air discharge mode to be performed during the set time.

A flow rate sensor may be provided in a water supply passage between the water supply valve and the tank or an outflow passage between the tank and the water discharge valve.

The controller may control the air discharge mode to be performed while the set flow rate is sensed through the flow sensor.

Preferably, the control unit counts the time after heading and performs the air discharge mode after a predetermined time (waiting time) has elapsed.

Preferably, when the outflow input is applied before the waiting time elapses, the control unit controls to start the counting and open the outflow valve to perform the outflow mode.

Preferably, when the outgoing input is applied during the execution of the air discharge mode, the controller may stop performing the air discharge mode and open the water discharge valve to perform the outflow mode.

Preferably, the control unit initiates the counting when an outgoing input is applied during the air discharge mode.

According to an aspect of the present invention, there is provided a control method for a direct water-type water purifier for discharging at least one of purified water, cold water, and hot water using the water pressure of an external water source, An outflow mode step of opening both a water supply valve for supplying water to the inside of the water purifier and an outflow valve for leaving water in the tank, and leaving the purified water outside the water purifier; The water supply valve is opened and the water outlet valve is closed to raise the pressure between the tank and the water outlet valve and the check valve provided between the tank and the water outlet valve is opened by the raised pressure, A control method of a water purifier including an air exhaust mode step of exhausting air can be provided.

And the check valve is provided to be opened at a pressure lower than the water pressure of the external water source.

Preferably, the air discharge mode step is performed during a predetermined time or while a predetermined flow rate is sensed.

And a determination step of determining an execution condition of the air discharge mode.

In the determining step, it is preferable to determine whether the counted waiting time has elapsed after the outgoing mode step has ended.

The tank may be a hot water tank for heating purified water, and the air discharge mode step may be performed when it is determined that the waiting time has elapsed after the hot water outflow mode step is completed.

And a reset step of resetting the standby time.

In the determination step, if the outgoing input is applied after the lapse of the waiting time, the outgoing mode step may be performed through the reset step.

Preferably, when the outgoing input is applied during the air exhaust mode step, the air exhaust mode step is stopped and the outgoing mode step is performed via the reset step.

Preferably, the air discharge mode step is performed automatically by the water purifier irrespective of the user's input.

According to one embodiment of the present invention, it is possible to provide a water purifier capable of substantially exhausting air in the tank.

According to one embodiment of the present invention, it is possible to provide a water purifier that can lower the influence of the operating pressure of the check valve upon air discharge.

According to an embodiment of the present invention, it is possible to provide a water purifier that can be introduced into the flow path from the outside of the water purifier or automatically discharge air generated in the flow path during use of the water purifier. . Accordingly, it is possible to provide a water purifier that can effectively prevent noise and water generated by the outflow of air with purified water.

It is possible to provide a water purifier and a control method thereof that can easily remove air by minimizing the addition of a complicated structure or structure and also by way of an embodiment of the present invention.

According to an embodiment of the present invention, it is possible to provide a water purifier and its control method capable of significantly reducing occurrence of water leakage in the water purifier internal flow path by minimizing a pressure rise value and a pressure rise time which are pressurized to the flow path inside the water purifier.

1 shows a water purifier that can be applied to a conventional or an embodiment of the present invention,
2 shows a piping diagram of a water purifier applicable to an embodiment of the present invention,
3 is a flowchart illustrating a control method of a water purifier applicable to an embodiment of the present invention.

Hereinafter, a water purifier according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 shows an example of a water purifier that can be applied to this embodiment. Hereinafter, a water purifier will be described with reference to Fig. 1. Fig.

The water purifier 10 may include a cabinet 11 and a dispenser 12 which form an external shape. Here, the dispenser 12 means a space where a user is supplied with drinking water. Therefore, generally, the dispenser 12 is formed in front of the cabinet 11. Of course, such a dispenser 12 can be formed in the form of a recessed or recessed space in front of the cabinet 11. But it may be formed in a protruding shape in front of the cabinet 110 as the case may be.

The dispenser 12 is provided with a cock 15 through which drinking water is discharged, and a lever 16 for operating drinking water may be provided. That is, when the user operates the lever 16, the drinking water can be discharged from the cock 15. Here, the operation of the lever 16 may be in the form of pushing or pulling the lever.

Specifically, the user lifts the cup 1 so that the upper portion of the cup 1 is positioned below the cock 15, and the cup 1 can be pushed while the cup 1 is in contact with the lever 16. According to the operation of the lever 16, the drinking water can be discharged from the cock 15 and stored in the cup 1.

The user can drink the water stored in the cup 1 and throw the remaining water into the tray 13. [ Of course, a small amount of residue falling from the cock 15 can also be stored in the tray 13. [ Therefore, generally, the tray 13 is positioned directly below the cock 15. That is, below the dispenser 12.

Drinking water can be either purified water, cold water or hot water. Of course, it may be various forms of beverage. Accordingly, a user interface 14 for selecting the drinking water to be discharged can be provided. Here, an integer is a filtered water of raw water. Therefore, hot water or cold water that has been heated or cooled can also be called a constant.

For example, the user may select hot water through the user interface 14. [ Then, after the cup 1 is positioned below the cock 15, the lever 16 can be pushed. By this operation, hot water is discharged from the cock 15 and the cup 1 is filled.

At this time, when the air flow inside the water purifier is filled with air, not only hot water but also air can be discharged. That is, noise may be generated while air is discharged from the cock 15, and hot water may be splashed into a user's hand due to air discharge.

Hereinafter, a piping structure of a water purifier applicable to an embodiment of the present invention will be described in detail with reference to FIG. By applying such a piping structure, the above-described technical problems can be solved.

Basically, the water purifier according to the present embodiment can filter the raw water to generate an integer, and the generated purified water can flow out through the cock. Hereinafter, since the piping structure is described, the rear end and the front end may refer to the upstream side and the downstream side with respect to the forward flow direction of the fluid, respectively. For example, the rear end of the filter may refer to the upstream side of the filter.

As shown in FIG. 2, the raw water flowing into the water purifier 10 through the external water supply can be converted into purified water through the filter 60. The configuration of the filter 60 may be variously modified, and the filter 60 may be constructed by a plurality of single filters. In FIG. 2, three single filters are connected in series to form the filter 60, but the present invention is not limited thereto.

Specifically, the filter 60 may include a pre-carbon filter 61, a UF filter 62, and a post-carbon filter 63. Of course, other types of filters may be added in some cases.

A water supply valve (25) may be provided between the external water supply and the front end of the filter (60). The water supply valve 25 may be provided in the water supply channel 20. When the water supply valve 25 is opened, raw water or purified water may flow through the water supply channel 20.

For example, when the water supply valve 25 is opened, the raw water may be supplied to the tank 50 after being converted into purified water through the filter 60. The flow path of the rear end of the filter 60 in the water supply flow path 20 may be referred to as a constant flow path 21. [ Therefore, only the purified water after the raw water is filtered is flowed into the purified water flow path 21.

The purified water generated by filtering the raw water can be discharged to the outside through the tank 50, the outflow channel 30 and the outlet valve 35 via the cock 15. For this outflow, the operation of the lever 16 shown in Fig. 1 is required, and the operation of the lever 16 causes the outflow valve 35 to be opened and the outflow can be performed.

The water purifier applied to the present embodiment may be a water purifier. That is, the water purifier can be a water purifier that can purge water by using the water pressure of the external water supply. Therefore, the water supply valve (25) as well as the water outlet valve (35) are opened together during heading. Therefore, it can be said that the filtering is performed together during the outgoing.

In addition, in the direct water type purifier, a continuous flow of purified water is generated from the water supply valve 25 to the water outlet valve 35. In other words, substantially all the flow rate of the water flowing from the water supply valve 25 is made to flow out through the water outlet valve 35. Therefore, when air is accumulated in the flow path, air can be discharged together with purified water.

On the other hand, the water purifier can be equipped not only with the purified water at room temperature but also by heating or cooling it, thereby allowing hot water or cold water to be discharged. Thus, a tank may be provided for receiving and heating or cooling the purified water. Of course, if necessary, a tank for accommodating the purified water at room temperature may be provided.

These tanks are relatively large in comparison with the flow paths having different cross-sectional areas, and the constants provided in the tanks are separately treated. Here, the water treatment may be various, such as heating, cooling, sterilization, etc., and may be performed in the tank.

Air introduced into the water purifier through the oil passage 20 may accumulate in the upper portion of the tank 50. Also, the air generated in the water treatment process inside the tank 50 may be accumulated in the upper portion of the tank 50. In particular, as the purified water is heated, the purified water is boiled, and thus, the air dissolved in the purified water can be accumulated in the upper portion of the tank 50 out of the purified water.

Here, the tank 50 may also be referred to as a flow path. That is, it can be regarded as a flow path directly receiving the water pressure of the external water supply. Therefore, basically, the inside of the tank 50 is completely filled with the purified water. For this purpose, it is preferable that the tank is a sealed tank in which the external water supply source is pressurized by the internal pressure.

In one example, the tank 50 may be a hot water tank. The heater 51 is provided in the hot water tank, and the purified water can be heated by driving the heater 51. At this time, the generated air can be accumulated in the upper part of the tank.

If a check valve is installed in a tank as in the prior art, a large amount of purified water may be discharged to the outside of the tank at each heating. When the operating pressure of the check valve is increased to prevent this, the check valve serves as a relief valve for safety and can not effectively perform the function of discharging unnecessary air.

According to the present embodiment, an exhaust passage 45 branched from the outflow passage 30 is provided to efficiently discharge accumulated air in the tank, and a check valve can be mounted on the exhaust passage 45. It is preferable that the exhaust passage 45 is branched between the tank 50 and the outlet valve 35.

The outflow channel 53 may be provided so as to communicate with the uppermost portion of the tank 50 so that the air inside the tank is effectively discharged from the inside of the tank. In addition, the water supply channel, particularly the water purification channel 21, may be provided so as to communicate with the lowermost portion of the tank 50 in order to smooth the inflow and outflow of the purified water into the tank 50.

A discharge port (53) is provided at the uppermost portion of the tank and an inlet (52) is provided at the lowermost portion of the tank. The discharge port 53 may be connected to the outflow channel 30 and the inlet port 52 may be connected to the purified water flow path 21.

Due to the characteristics of the water purifier and the characteristic of connection between the tank 53 and the outflow channel 30, the air in the tank 53 is discharged before the water purifier. Therefore, the air in the tank 53 can be safely and effectively removed by discharging the air in the tank 53 to a place other than the coke. That is, the air in the tank 53 can be discharged to the outside through the check valve 45 via the exhaust passage 40. For example, it is possible to discharge air through a water outlet outside a water purifier or a water outlet in a sink.

The check valve 45 may be a check valve similar to that of the prior art. That is, it may be a check valve provided to open at a predetermined operating pressure. Here, the operating pressure is preferably lower than the hydraulic pressure of the external water supply.

On the other hand, when both the water supply valve 25 and the water discharge valve 35 are opened for the performance of the heading mode, the pressure in the water discharge valve 35 becomes the lowest. Therefore, substantially all the air and purified water on the flow path are discharged through the above-mentioned water discharge valve 35.

However, when the water feed valve 25 is opened and the water outlet valve 35 is closed, the water pressure of the external water supply and reception affects the entire flow path inside the water purifier. That is, the water pressure that is substantially equal to the water pressure of the external water supply / discharge in the flow path between the water supply valve 25 and the water outlet valve 35 is generated.

As described above, when the operating pressure of the check valve 45 is lower than the water pressure of the external water supply, and only the water supply valve 25 is opened, the check valve 45 is opened. Therefore, the air accumulated in the tank 50 is discharged to the outside through the check valve 45 at the lowest pressure. Of course, not only air but also some constants can be discharged at this time.

The air discharge mode is differentiated from the outgoing mode by discharging air through the check valve (45). That is, an air discharge mode may be performed in which air is discharged through the check valve using the pressure of external water supply through the opening of the water supply valve 25 and the closing of the water discharge valve 35.

The heading mode is performed only when a user's input is applied, such as when the user operates the lever 16. [ However, the air discharge mode can be automatically performed irrespective of the user's input.

The execution of the outgoing mode and the air exhausting mode can be performed by controlling the various valves in the control unit 80. Of course, the control portion is not directly involved in the operation of the check valve 45. [ The control unit can directly control the water supply valve 25 to be opened and the water outlet valve 35 to be closed in the air discharge mode so that the check valve 45 is indirectly opened.

Of course, the control unit 80 can control the driving of the heater 51 as well as the water supply valve and the water outlet valve. In addition, it may be provided to control the operation of the water purifier according to a predetermined algorithm according to the flow rate sensed by the flow sensor 70.

On the other hand, the performance of the air discharge mode can be controlled by time or flow rate. In one example, the air discharge mode can be controlled to be performed for a predetermined time. For example, approximately three seconds may be controlled so that the air discharge mode is performed.

Also, the air discharge mode may be controlled to be performed until a predetermined flow rate is sensed. The flow sensor 70 may further be provided to detect the flow rate. The flow sensor 70 senses a flow rate passing through the flow path and may be provided in any one of the purified water flow path 21 and the outflow path 42.

The flow sensor is a sensor for sensing a constant flow rate, not an air flow rate. Therefore, it is more preferable to install it on the front end of the tank 52. This is because the error of the flow rate sensing may be large due to the air discharge at the rear end of the tank 52.

Therefore, the air discharge mode may be performed until the predetermined flow rate is sensed through the flow sensor 70 (i.e., until it is determined that a predetermined flow rate has been introduced into the tank).

Of course, the performance of the air discharge mode can be controlled using both factors, not time or flow.

Hereinafter, a control method of a water purifier according to an embodiment of the present invention will be described in detail with reference to FIG.

The control method of the water purifier according to the present embodiment may include an outgoing mode step S10 and an air exhaust mode step S40.

In the outgoing mode step S10, for example, at least one of purified water, hot water, and cold water is allowed to flow through the cock 15 as the user operates the lever 16. [ The outgoing mode step S10 may be performed until the lever operation is released. Therefore, the outgoing mode step S10 may be a step recognized by the user, and may be performed according to the input of the user.

The air discharge mode step S40 may be a step that the user does not recognize, and may be performed independently of the user's input.

When the air discharge mode step S40 is started (S41), the water supply valve 25 is opened (S42). Of course, the water outlet valve 35 is not opened at this time. The opening of the water supply valve 25 is performed until a predetermined condition is satisfied. That is, it is determined whether the flow rate condition or the time condition is satisfied (S44). If the condition is satisfied, the water supply valve 25 is closed (S45) and the air discharge mode step is ended (S45).

Meanwhile, the air discharge mode step S40 is performed by opening the water supply valve 25 and closing the water discharge valve 35, which means that the pressure of the flow path inside the water purifier is increased. Therefore, it is not preferable that the external water pressure is continuously applied to the flow path of the water purifier due to the water leakage problem or the like. Therefore, it is preferable that the air discharge mode step be performed for a relatively short time or during a very small flow rate. For example, it can be carried out for about 3 seconds or while a flow rate of 20 to 60 cc is generated.

Likewise, it is preferable that the execution of the air discharge mode is performed at a time when air discharge is required.

As described above, generation and accumulation of air are the greatest when hot water is generated in the hot water tank. Therefore, it is preferable that the air discharge mode is performed after the hot water is discharged after the cold water or the purified water is not discharged. This is because, after the hot water is taken out, the step of heating the purified water introduced into the new hot water tank is basically carried out.

On the other hand, this air discharge mode is a function incidental to the outbound mode. That is, it is preferable that the outgoing mode takes precedence over the air exhaust mode. This is because the user suspects the failure of the water purifier if the user does not perform the outflow while the lever is depressed (by performing the air exhaust mode).

In order to minimize the relationship between the outgoing mode and the air discharge mode, the effective air discharge and the over-pressure exposure on the flow passage, the control method according to the present embodiment further includes a judgment step (S30) of judging an execution condition of the air discharge mode .

If the condition is satisfied in the determining step S30, the air discharge mode step S40 is performed. If the condition is not satisfied, the air discharge standby state is maintained.

Here, the above condition may be whether or not the waiting time has elapsed after the outgoing. That is, when the predetermined waiting time (for example, 30 seconds) has elapsed after the outgoing, the air discharge mode step S40 may be performed. Here, the outflow can be the outflow of hot water, not the outflow of cold water or purified water. Accordingly, when the waiting time elapses after the lever operation cancellation for taking out the hot water occurs (S20), the air discharge mode step S40 may be performed.

On the other hand, the user can operate the lever for the re-release even after the wait time elapses from the time of departure. Accordingly, when the outgoing input is generated during the execution of the determination step, the outgoing mode S10 is performed. In the determining step S30, the outflow input may be not only the hot water but also the outflow input of an integer or cold water. This is because, in any case, it is preferable to control the heading mode to have priority over the air discharge mode.

The waiting time can be counted when the operation of the hot water lever is released. For example, when the waiting time is 30 seconds, the air discharge mode step may be automatically performed when 30 seconds elapses after the operation of the hot water lever is released.

However, for example, the levers for watering can be operated 20 seconds after the hot water lever operation is released. Therefore, it is preferable to reset the counted time at this time (S50). After the resetting step S50, the corresponding heading mode is performed. For example, the time may not be counted when the cold water out mode is performed. And, after the hot water out mode is performed, the time can be counted again.

On the other hand, the heading input can be performed not only during the step S30 of determining whether the air discharge mode is performed or not, but also during the air discharge mode. That is, the outflow input can be performed when the air discharge mode is not completed. Therefore, it is possible to determine whether there is an outgoing input during the air discharge mode (S43). When there is an outgoing input, the air discharge mode is stopped, and the corresponding outgoing mode is performed through the reset step (S50).

Therefore, according to the control method of the present embodiment, it is possible to prevent the air discharge mode from being performed frequently. In addition, the air discharge mode can be performed at the optimum time. This makes it possible to effectively reduce the frequency and time at which the internal flow path is exposed to high pressure as well as the effective discharge of air.

10: Water purifier 15: Cork
16: Lever 20: Water supply channel
21: purified water flow path 25: water supply valve
30: Outflow channel 35: Outflow valve
40: Exhaust flow path 45: Check valve
50: tank (hot water tank) 60: filter
70: Flow sensor 80:

Claims (24)

Wherein at least one of purified water, cold water and hot water is discharged using the water pressure of the external water source itself,
A filter for filtering the raw water to generate an integer;
A tank for receiving purified water;
A water supply passage provided between the filter and the tank to supply purified water to the tank;
A coke for leaving out the purified water in the tank;
An outflow channel for supplying purified water in the tank to the cock;
An exhaust passage branching from the outflow channel; And
And a check valve provided in the exhaust passage and opened to discharge air in the tank at a pressure lower than the water pressure of the external water source. The method according to claim 1,
Wherein the tank is a sealed tank in which the external water source is pressurized to an internal pressure by a water pressure. 3. The method of claim 2,
Wherein the tank is a hot water tank for heating the water purified water. The method according to claim 1,
And the outflow channel is connected so as to communicate with the uppermost portion of the tank. 5. The method of claim 4,
Wherein the water supply channel is connected to the lowermost portion of the tank. The method according to claim 1,
A water supply valve opened to supply said raw water to said filter; And
Wherein the water purifier includes an outlet valve in which the purified water is opened for leaving the cock. The method according to claim 6,
And a controller for controlling the air supply valve to be opened and the water outlet valve to be closed so that the air is exhausted through the check valve. 8. The method of claim 7,
Wherein the control unit controls the air discharge mode to be performed during a set time. 8. The method of claim 7,
Wherein a water flow sensor is provided in a water supply passage between the water supply valve and the tank or an outflow passage between the tank and the water outlet valve. 10. The method of claim 9,
Wherein the control unit controls the air discharge mode while the set flow rate is sensed through the flow sensor. 8. The method of claim 7,
Wherein the control unit counts time after heading and performs the air discharge mode after a predetermined time (waiting time) has elapsed. 12. The method of claim 11,
Wherein the control unit controls the counting to be initiated when the outflow input is applied before the waiting time elapses, and to perform the outflow mode by opening the outflow valve. 12. The method of claim 11,
Wherein the control unit stops the air discharge mode operation and opens the water discharge valve to perform the water discharge mode when the water supply input is applied during the air discharge mode. 14. The method of claim 13,
Wherein the control unit initiates the counting when an outgoing input is applied during the air discharge mode. A method for controlling a direct water-type water purifier in which at least one of purified water, cold water and hot water is taken out using the water pressure of an external water source itself,
An outflow mode step of opening both the water supply valve for supplying the raw water to the inside of the water purifier and the outflow valve for leaving the water in the tank, and leaving the purified water outside the water purifier; And
The water supply valve is opened and the water outlet valve is closed to raise the pressure between the tank and the water outlet valve and the check valve provided between the tank and the water outlet valve is opened by the raised pressure, And an air exhaust mode step of exhausting the air. 16. The method of claim 15,
Wherein the check valve is provided to open at a pressure lower than the water pressure of the external water source. 16. The method of claim 15,
Wherein the air discharge mode step is performed during a predetermined time or while a predetermined flow rate is sensed. 16. The method of claim 15,
And a determination step of determining an execution condition of the air discharge mode. 19. The method of claim 18,
Wherein the determining step determines whether an elapse of a waiting time counted after the outgoing mode step is completed. 20. The method of claim 19,
The tank is a hot water tank for heating purified water,
Wherein the air discharge mode step is performed when it is determined that the waiting time has elapsed in the determining step after the end of the hot water outflow mode step. 20. The method of claim 19,
And a resetting step of resetting the waiting time. 22. The method of claim 21,
Wherein when the outflow input is applied after the waiting time elapses in the determining step, the outgoing mode step is performed through the reset step. 22. The method of claim 21,
Wherein when the outgoing input is applied during the air exhaust mode step, the air exhaust mode step is stopped and the outgoing mode step is performed through the reset step. 16. The method of claim 15,
Wherein the air discharge mode step is performed automatically by the water purifier irrespective of a user's input.

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