KR20150020972A - Water Provider with Electrolyzer and Control Method thereof - Google Patents

Abstract

The present invention relates to a water supply device having an electrolyzer, including the electrolyzer that electrolyzes room-temperature water or cold water; a power supply unit that supplies power to the electrolyzer; a current detection unit that detects a current flowing in the electrolyzer; and a control unit that blocks the power supplied from the power supply unit to the electrolyzer in a case where an electrolyzer current value received from the current detection unit exceeds a current reference value.

Description

Technical Field [0001] The present invention relates to a water supply apparatus having an electrolytic cell,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply device, and more particularly, to a water supply device having an electrolytic cell such as an ionizer, a hydrogen generator and the like, and a control method thereof.

Generally, an ionizer or a hydrogen generator is provided with a filter unit for filtering and purifying the incoming water, an electrolytic cell for electrolyzing purified water from the filter unit to generate drinking water or hydrogen water, and electrolyzed ionized water or hydrogenated water from the electrolytic cell A power supply unit for converting the input AC power into a DC power and applying it to the electrolytic cell, and a control unit for controlling the power supply unit to supply electric power to the electrolytic cell.

An electrolytic cell usually consists of a part and an outlet, a case, a plurality of electrodes fixed inside the case, and a plug connected to the electrode and the power unit. In the case, a plurality of support frames are stacked and coupled with bolts or the like, and the electrodes are fixed in the support frames. Room temperature water or cold water enters the inlet of the case, and ionized water or hydrogen water is discharged by electrolysis at room temperature or cold water to the outlet provided at the other side.

The control unit keeps the current flowing in the electrolytic bath at a constant operating range. However, because water contains different components, the electrical conductivity varies from water to water. As a result, when an ionizer or a hydrogen generator having an electrolytic cell is used in a different region, the electric conductivity in the electrolytic cell is rapidly increased due to a specific component contained in the water in the region, and the instantaneous overcurrent flows to the electrolytic cell, Or the electrolytic cell is damaged. In particular, instantaneous overcurrents frequently occur in water containing a large amount of salinity.

The control unit controls the power supply unit to continuously supply power to the electrolytic bath when the discharge valve is opened and the electrolyzed ionized water or hydrogen water is discharged to the outside. However, if the discharge valve fails and the discharge valve is not actually opened or the pipe is clogged even though the valve opening signal is received from the discharge valve, electric power continues to be supplied to the electrolytic cell in a state in which the ionized water or the hydrogen water in the electrolytic cell is not discharged to the outside Thereby causing gas such as hydrogen to accumulate in the electrolytic cell, causing the electrolytic cell to swell, eventually leading to the electrolytic cell popping up. In this case, the water temperature inside the electrolytic cell increases, and the electrolytic cell may melt.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems,

First, the power supply unit is prevented from being damaged due to an overcurrent in the electrolytic cell,

Second, the object of the present invention is to prevent the breakage of the electrolytic cell which may occur due to the accumulation of hydrogen gas or the like in the electrolytic cell due to excessive water temperature in the electrolytic cell.

To attain the above object, the water supply apparatus of the present invention comprises an electrolytic bath, a power supply unit, a current sensing unit, and a control unit.

The electrolytic cell electrolyzes room temperature water or cold water to generate ionized water or hydrogenated water.

The power supply unit supplies electric power to the electrolytic cell, and can use an SMPS (Switching Mode Power Supply) or the like.

The current sensing unit senses the current flowing through the electrolytic cell.

When the electrolytic cell current value received from the current sensing unit exceeds the current reference value, the control unit cuts off power supplied from the power supply unit to the electrolytic cell.

The water supply device of the present invention includes a discharge valve and a flow rate sensing portion.

The discharge valve is disposed at the rear end of the electrolytic cell, and discharges ionized water or hydrogenated water that is electrolyzed by ordinary temperature water or cold water to the outside.

The flow rate sensing unit is provided between the electrolytic cell and the discharge valve, and outputs a flow rate sensing signal indicating whether the electrolyzed normal temperature water or cold water is moving.

When the control unit receives the valve opening signal from the discharge valve, it determines whether the ionized water or the hydrogenated water is moved from the flow rate sensing signal. The control unit cuts off power supplied from the power supply unit to the electrolytic cell when it is determined that the ionized water or the hydrogenated water does not move.

The water supply device of the present invention includes a temperature sensing portion.

The temperature sensing unit senses the temperature of the electrolytic cell.

When the temperature of the electrolytic bath received from the temperature sensing unit exceeds the temperature reference value, the control unit cuts off power supplied from the power supply unit to the electrolytic bath.

In the water supply device of the present invention, the temperature sensing part is installed on the body or the surface of the electrolytic bath to sense the temperature of the body or surface of the electrolytic bath.

A method of controlling an electrolyzer of a water supply device according to the present invention includes: a step in which a control unit receives an electrolytic cell current value from a current sensing unit; The control unit comparing the electrolytic cell current value with the current reference value; And the control unit interrupts power supplied from the power supply unit to the electrolytic cell when the electrolytic cell current value exceeds the current reference value.

In the electrolytic cell control method of the present invention, the control unit receives the valve opening signal from the discharge valve provided at the rear end of the electrolytic cell; The control unit receiving the flow rate sensing signal from the flow rate sensing unit provided between the rear end of the electrolytic cell and the discharge valve or receiving the electrolytic cell temperature value from the temperature sensing unit installed in the electrolytic cell; And blocking the power supplied from the power supply unit to the electrolytic cell when the control unit determines that the electrolyzed normal temperature water or cold water does not move from the flow rate sensing signal or that the electrolytic cell temperature value exceeds the temperature reference value have.

According to the water supply device and the electrolytic bath control method according to the present invention, it is possible to prevent the overcurrent from flowing in the electrolytic bath, thereby preventing the power supply from being damaged. In addition, it is possible to prevent the electrolytic cell from being damaged by preventing excessive accumulation of gas such as hydrogen in the electrolytic cell or by preventing the water in the electrolytic cell from becoming too hot.

1 shows a first embodiment of a water supply device according to the present invention.
Fig. 2 shows a second embodiment of the water supply device according to the present invention.
3 shows a third embodiment of the water supply device according to the present invention.
4 shows a fourth embodiment of the water supply device according to the present invention.
5 shows a first embodiment of a method of controlling an electrolyzer of a water supply device according to the present invention.
6 shows a second embodiment of a method of controlling an electrolyzer of a water supply device according to the present invention.
7 shows a third embodiment of the electrolytic bath control method of the water supply apparatus according to the present invention.

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

1 shows a first embodiment of a water supply device according to the present invention.

1, a water supply apparatus having an electrolytic cell includes a filter unit 110, a cold water tank 210, a cold water valve 211, a hot water tank 220, a hot water valve 221, a hot water valve 231, An electrolyzer 310, a power supply unit 410, a discharge valve 511, a current sensing unit 610, a controller 710, and the like.

The filter unit 110 is an apparatus for purifying tap water or water in a water storage tank, and can be variously classified according to the type of the filter and the connection method. In general, the filter unit 110 uses a combination of filters having specific functions depending on the use purpose.

When the filter unit 110 is classified according to the function, there are a hollow fiber membrane filter system, a spiral filter system, a reverse osmosis filter system and a natural load filter system. (PRE) carbon filter to remove odor, chlorine, prohalomethane, etc .; hollow fiber membrane (UF) membrane filter to remove various heavy metal organic chemicals; ) Three-port membrane filter, or reverse osmosis (RO) membrane filter, post-treatment (POST) carbon filter for improving water taste and removing gas and odor. Generally, the domestic filter is used by connecting a sediment filter, a pretreatment carbon filter, a hollow fiber membrane filter, a post-treatment filter, and a functional filter in this order.

The cold water tank 210 cools the purified water passing through the filter unit 110 and stores the cooled water. For example, a plurality of refrigerant pipes are installed on the outer surface of the cold water tank 210, Can be configured.

The hot water tank 220 heats and stores the purified water that has passed through the filter unit 110. For example, the hot water tank 220 may be provided with heating means on the outer surface of the hot water tank 220, And an instantaneous heater is installed between the first and second heat exchangers.

There are provided a plurality of valves such as a cold water valve 211, a hot water valve 221, a hot water valve 511 and an ionized water / water discharge valve 511. These valves are controlled by the control unit 710, Respectively. Also, at least the operation signals of the ion / water discharge valve 511 among the operation signals of these valves are transmitted to the control unit 710. These valves can use, for example, a solenoid valve or the like.

The electrolytic bath 310 includes a case, an electrode, a plug, an inlet, an outlet, and the like. In the case, a plurality of support frames are stacked and coupled with a bolt or the like, and electrodes are fixed inside each support frame. Each electrode is connected to a plug, and the plug is connected to a power supply unit 410. Room temperature water or cold water enters the inlet provided on one side of the case, and ionic water or hydrogen water generated by electrolysis of room temperature water or cold water is discharged to the outlet of the other side.

The power supply unit 410 supplies power to the electrolyzer 310 and includes an AD converter, a switching unit, a smoothing unit, and the like, and performs PWM control to maintain a constant voltage. Accordingly, the power supply unit 410 applies a voltage of a predetermined magnitude to the electrolyzer 310.

The current sensing unit 610 measures a current flowing in the electrolyzer 310 and includes a resistance unit connected to a plug or an electrode of the electrolytic cell to mirror the electrolytic cell current, an amplification unit to amplify the mirrored electrolytic current, And transmits the amplified electrolytic bath current value to the controller 710.

The control unit 710 determines whether the current of the electrolyzer 310 is abnormal based on the electrolytic cell current value received from the current sensing unit 610. The control unit 710 maintains the current flowing through the electrolytic bath 310 at a normal operating range of 1.3 to 1.8 A. When the electrolytic bath current value received from the current sensing unit 610 reaches a set current reference value, for example, 2A (ampere) , And if it exceeds 3 A, the electric power supplied to the electrolytic bath 310 is cut off. The power cutoff may control the power supply unit 410 or the electrolytic cell 310. [

The control unit 710 monitors the electrolytic cell current value received from the current sensing unit 610 even after the power supplied to the electrolytic cell 310 is shut off and if the received electrolytic cell current value falls below the current reference value or within the operating range, The power supply unit 410 or the electrolytic bath 310 may be controlled to supply power again to the power supply unit 310.

The control unit 710 may cause a warning sound to be emitted when the electrolytic cell current value received from the current sensing unit 610 repeats the current reference value a predetermined number of times, for example, two or more times.

Fig. 2 shows a second embodiment of the water supply device according to the present invention.

As shown in FIG. 2, the second embodiment further includes a flow sensing unit 810 as a modification of the first embodiment.

The flow rate sensing unit 810 is installed between the electrolyzer 310 and the ion water / hydrogen discharge valve 511. The flow rate sensing unit 810 senses whether the ionized water or hydrogen water discharged from the electrolyzer 310 flows along the pipe, 710).

The control unit 710 receives the flow rate sensing signal from the flow rate sensing unit 810 when receiving the valve opening signal from the ion water / The control unit 710 determines whether the ionized water or hydrogen discharged after being electrolyzed in the electrolyzer 310 is moved along the pipe from the flow rate sensing signal. The control unit 710 cuts off power supplied from the power supply unit 410 to the electrolyzer 310 when it is determined that the ionized water or the hydrogen water does not move.

The control unit 710 receives the flow rate sensing signal received from the flow rate sensing unit 810 even after the power supplied to the electrolytic cell 310 is shut off and determines that the ionized water or the hydrogen flow rate is shifted from the received flow rate sensing signal The power supply unit 410 or the electrolytic bath 310 to supply power to the electrolytic bath 310 again.

The control unit 710 may generate a warning sound when the flow rate sensing signal received from the flow rate sensing unit 810 repeats a predetermined number of times, for example, two or more times, that the ionic water or the hydrogen water does not move.

3 shows a third embodiment of the water supply device according to the present invention.

As shown in FIG. 3, the third embodiment further includes a temperature sensing unit 910 as another modification of the first embodiment.

The temperature sensing unit 910 is embedded in the case itself of the electrolyzer 310 or installed on the case surface and senses the case temperature of the electrolyzer 310 to transmit the electrolytic cell temperature value to the controller 710.

The temperature sensing unit 910 can use a thermistor whose resistance varies with temperature. A thermistor is an oxide-based ceramic such as NiO (PTC thermistor), which uses resistance-decreasing material (NTC thermistor) when the temperature rises. , MgO, MnO, and the like.

The control unit 710 may cut off power supplied from the power supply unit 410 to the electrolytic cell 310 when the electrolytic cell temperature value received from the temperature sensing unit 910 exceeds a temperature reference value, do.

The control unit 710 controls the power supply unit 410 and the electrolytic bath 310 when the electrolytic bath temperature value received from the temperature sensing unit 910 falls below the temperature reference value even after the power supplied to the electrolytic bath 310 is cut off So that electric power can be supplied to the electrolytic bath 310 again.

The control unit 710 may cause a warning sound to be emitted when the electrolytic bath temperature value received from the temperature sensing unit 910 exceeds a reference temperature value a predetermined number of times, for example, twice or more.

4 shows a fourth embodiment of the water supply device according to the present invention.

As shown in FIG. 4, the fourth embodiment is a modification of the first embodiment and includes both the flow rate sensing portion 810 of the second embodiment and the temperature sensing portion 910 of the third embodiment.

The control unit 710 receives the flow rate sensing signal from the flow rate sensing unit 810 and the electrolytic cell temperature value from the temperature sensing unit 910 in the case of including both the flow rate sensing unit 810 and the temperature sensing unit 910 . The control unit 710 cuts off power supplied from the power supply unit 410 to the electrolyzer 310 when it is determined that the ionized water or the hydrogen water does not move from the flow rate sensing signal or the electrolytic bath temperature value exceeds the temperature reference value. In addition, the controller 710 may sequentially determine the flow rate sensing signal and the temperature of the electrolyzer, and control the power supplied from the power supply unit 410 to the electrolyzer 310 to be cut off.

The control unit 710 controls the power supply unit 410 and the electrolytic cell 310 so that the electrolytic cell 310 is powered again when the electrolytic cell temperature value is lower than the temperature reference value To be supplied.

5 shows a first embodiment of a method of controlling an electrolyzer of a water supply device according to the present invention.

The electrolytic bath control method of the first embodiment controls the operation of the electrolytic bath 310 by sensing a current flowing through the electrolytic bath 310.

First, when the current sensing unit 610 installed in the electrolyzer 310 senses the current flowing through the electrolyzer 310 and transmits the electrolyzer current value to the controller 710, the controller 710 receives the electrolyzer current value S11).

The control unit 710 compares the received electrolytic cell current value with the current reference value (S13). The current reference value is selected at a current value lower than the upper limit current value at which the power supply unit 410 is destroyed. For example, if the operation current of the electrolyzer is controlled in the range of 1.3 to 1.8 A and the upper limit current value of the power supply unit 410 is 4 A, the current reference value can be set to be lower than 4 A, for example, 3A or 3.5 A .

The control unit 710 controls the power supply unit 410 and the electrolytic bath 310 to shut off the power supplied to the electrolytic bath 310. When the electrolytic bath current value exceeds the current reference value The power supply to the electrolyzer 310 is maintained even if the electrolyzer is out of the operating range of the electrolyzer.

6 shows a second embodiment of a method of controlling an electrolyzer of a water supply device according to the present invention.

6, the electrolytic cell control method of the second embodiment additionally determines the flow rate sensing signal of the flow rate sensing unit 810 in addition to the electrolytic cell current value of the current sensing unit 610 and determines whether the electrolyzer 310 is operating .

If the ionized water or hydrogen generated in the electrolytic cell 310 is not discharged out of the electrolytic cell 310 even if the electrolytic cell current value received from the current sensing part 610 does not exceed the current reference value in the first embodiment, It is necessary to monitor whether the produced ionized water or hydrogen is discharged to the outside because the gas such as hydrogen is excessively filled in the electrolytic bath 310 and the electrolytic bath 310 may swell or burst.

6, when the control unit 710 determines that the electrolytic cell current value received from the current sensing unit 610 is below the operation range or the current reference value of the electrolytic cell 310, the control unit 710 additionally outputs the ionic / 511 is received (S21).

The control unit 710 receives the valve opening signal of the ion water / hydrogen discharge valve 511 and receives the flow rate sensing signal from the flow rate sensing unit 810 (S23). If the valve opening signal is not received, (S27). ≪ / RTI >

The controller 710 analyzes the received flow rate sensing signal to determine whether ionized water or hydrogen water is actually discharged from the rear end of the electrolyzer 310 (S25).

The control unit 710 continuously supplies the electric power to the electrolytic cell 310 at step S27 if it is determined that the ionized water or the hydrogen water is moving along the pipe, (Step S15).

7 shows a third embodiment of the electrolytic bath control method of the water supply apparatus according to the present invention.

7, in the electrolytic cell control method of the third embodiment, the electrolytic cell temperature value of the temperature sensing unit 910 is additionally determined in addition to the electrolytic cell current value of the current sensing unit 610, .

In the case where the current sensing unit 610 fails or the generated electrolytic cell current value received from the current sensing unit 610 does not exceed the current reference value in the first embodiment, The ionized water or the hydrogen in the electrolytic bath 310 may be rapidly heated. Therefore, it is necessary to additionally monitor the temperature of the water in the electrolyzer 310.

7, the control unit 710 receives the electrolytic cell temperature value from the temperature sensing unit 910 (S31), and determines whether the electrolytic cell temperature value exceeds the temperature reference value (S33). The temperature reference value may vary depending on the temperature at which the electrolyzer 310 can resist heat, that is, the material of the electrolyzer 310. For example, the temperature reference value may be selected as 30 ° C, 50 ° C, 70 ° C, or even 100 ° C. This is because the temperature of the electrolytic bath 310 itself refers to the temperature of the electrolytic bath 310 itself because it is disadvantageous in terms of cost and the like to directly measure the temperature of the inside water by installing the temperature sensing unit 910 inside the electrolytic bath 310. However, it is not excluded that the temperature sensing unit 910 is configured to directly touch the water inside the electrolytic bath 310.

The control unit 710 controls the power supply unit 410 and the electrolytic bath 310 to shut off the power supplied to the electrolytic bath 310 (S15). If the electrolytic bath temperature value is lower than the reference temperature value If the temperature reference value is not exceeded, power is continuously supplied to the electrolyzer 310 (S35).

6 and 7, it has been described that the flow sensing and the temperature sensing are performed selectively. However, the flow sensing is performed first and the temperature sensing is performed according to the result, that is, the flow sensing and the temperature sensing are sequentially / It may be configured to determine whether or not to operate.

While the invention has been described in terms of several embodiments, it is to be understood that the invention is not limited thereto. Those skilled in the art will appreciate that various modifications and changes may be made based on this embodiment. Accordingly, the scope of the present invention should be determined by the following claims, and variations and modifications made by those skilled in the art can be construed as being included in the scope of the present invention.

110: filter unit 210: cold water tank
220: hot water tank 310: electrolyzer
410: Power supply unit 511: Discharge valve
610: current sensing unit 710:
810: Flow rate sensing unit 910: Temperature sensing unit

Claims (6)

In the water supply device,
An electrolytic bath for electrolyzing room temperature water or cold water;
A power supply unit for supplying electric power to the electrolytic bath;
A current sensing unit for sensing a current flowing in the electrolytic bath;
And a control unit for shutting off power supplied from the power supply unit to the electrolytic cell when the electrolytic cell current value received from the current sensing unit exceeds a current reference value. The method according to claim 1,
A discharge valve installed at the rear end of the electrolytic cell for discharging the electrolyzed cold water or cold water; And
And a flow rate sensing unit provided between the electrolytic cell and the discharge valve for outputting a flow rate sensing signal indicative of movement of the electrolyzed cold water or cold water,
Wherein the control unit determines whether the electrolyzed cold water or the cold water has been moved from the flow rate sensing signal when the valve opening signal is received from the discharge valve and if the electrolyzed cold water or cold water does not move, And shutting off power supplied to the electrolytic cell. 3. The method according to claim 1 or 2,
And a temperature sensing unit for sensing the temperature of the electrolytic bath,
Wherein the control unit cuts off power supplied from the power supply unit to the electrolytic cell when the temperature of the electrolytic bath received from the temperature sensing unit exceeds a temperature reference value. The apparatus of claim 3, wherein the temperature sensing unit
And an electrolytic bath provided on the body or surface of the electrolytic bath for sensing the temperature of the body or surface of the electrolytic bath. A control method for a water supply apparatus having an electrolytic cell,
The control unit receiving the electrolytic cell current value from the current sensing unit;
Comparing the electrolytic cell current value with a current reference value;
And the control unit interrupts power supplied from the power supply unit to the electrolytic cell when the electrolytic cell current value exceeds the current reference value. 6. The method of claim 5,
The control unit receiving a valve opening signal from a discharge valve provided at a rear end of the electrolytic bath;
The control unit receiving a flow rate sensing signal from a flow rate sensing unit provided between a rear end of the electrolytic cell and the discharge valve or receiving an electrolytic bath temperature value from a temperature sensing unit installed in the electrolytic bath;
Wherein the control unit determines that the electrolyzed normal temperature water or cold water does not move from the flow rate sensing signal or if the electrolytic bath temperature value exceeds the temperature reference value, Wherein the electrolytic cell is a water supply device.

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