KR100669024B1 - Control method of ion generator - Google Patents

Abstract

The control method of the ion generating device according to the present invention detects and displays a defective state of bonding of metals to generate ions, disconnection of power lines, and complete consumption of metals, so that the user can check and take action. have. The control method of the ion generating device according to the present invention for this purpose, by applying a control voltage for the electrolysis to the ion generating device to generate ions according to the electrolysis in the ion generating device; Detect a magnitude of a drive current flowing through the metal as a control voltage is applied; When the magnitude of the driving current decreases to a preset magnitude, it is determined that the electrolysis is not performed in the ion generating device, and this is displayed through the display unit.

Description

CONTROL METHOD OF ION GENERATOR}

1 is a cross-sectional view of a washing machine having a silver ion generating device according to an embodiment of the present invention.

FIG. 2 is a sectional view of the ion generating device shown in FIG. 1. FIG.

3 is a block diagram showing a control system of the washing machine shown in FIG.

4 is a circuit diagram showing a driving unit of the ion generating device shown in FIG. 1;

5 is a flow chart showing a control method of an ion generating device according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control method of an ion generating device, and more particularly, to a control method of an ion generating device that generates ions for sterilizing laundry or tableware.

Sterilizing washing machines include ozone and silver ions. Among them, a washing machine using silver solution is a sterilizing water supply device that manufactures and supplies a silver solution to sterilize laundry through antibacterial and sterilizing action of silver solution. It is a washing machine adopted.

The silver solution is dissolved in water by generating silver ions (Ag +), and is also used as an antibacterial or bactericide. The silver solution has been reported to sterilize (sterilize) about 650 kinds of bacteria. In particular, silver solution, unlike other antibiotics, is characterized by no resistance and is very safe because it is not toxic at all. The silver solution can be prepared by electrolysis, chemical decomposition, or grinding. The most effective of these is the electrolysis method, which dissolves and dissolves silver ions in water.

In addition to silver (Ag), other metals may be used to generate ions through electrolysis. If these metals are consumed by electrolysis or broken by breakage, they cannot normally generate ions. You can't expect the action.

The control method of the ion generating device according to the present invention detects and displays a defect in the state of bonding of metals to generate ions, disconnection of power lines, and exhaustion of metals. have.

The control method of the ion generating device according to the present invention for this purpose, by applying a control voltage for the electrolysis to the ion generating device to generate ions according to the electrolysis in the ion generating device; Detect a magnitude of a drive current flowing through the metal as a control voltage is applied; When the magnitude of the driving current decreases to a preset magnitude, it is determined that the electrolysis is not performed in the ion generating device, and this is displayed through the display unit.

If it is determined that the electrolysis is not performed, the supply of the control voltage is stopped to stop the electrolysis.

In addition, the preset value is 0 amps (A).

In addition, the electrolysis is stopped when the state in which the driving current maintains the predetermined value or more continues for a predetermined time or more.

Referring to Figures 1 to 5 a preferred embodiment of the present invention made as described above are as follows. 1 is a cross-sectional view of a washing machine having a silver ion generating device according to an embodiment of the present invention. As shown in FIG. 1, a water tank 104 is installed inside the main body case 102 for fresh water of the wash water, and a washing tank 106 is installed inside the water tank 104 so as to be rotatable. In addition, a pulsator 108 for forward and reverse rotation is installed in the washing tank 106 to form a washing stream, and a lower portion of the water tank 104 drives to rotate the washing tank 106 and the pulsator 108. The device 110 is installed. The drive device 110 is composed of a drive motor 112 and a power transmission device (114). The drive motor 112 is rotated by receiving power, and the power transmission device 114 allows this rotational force to be selectively transmitted to the pulsator 108 and the washing tank 106. A belt 116 for transmitting power is connected between the drive motor 112 and the power transmission device 114. In FIG. 1, reference numeral 120 designates an ion generating device, 122 designates a storage container, 128 designates a discharge pipe, and 118a designates a drain pipe.

FIG. 2 is a cross-sectional view of the ion generating device shown in FIG. 1. As shown in FIG. 2, when laundry is put into a washing machine and a washing course is set after power is supplied, washing water is supplied into the water tank 104. The wash water being supplied is dissolved in the detergent while passing through a detergent dissolving device (not shown), and is supplied into the water tank 104 together with the detergent.

When the user selects the sterilization washing course, the inlet valve 204 of the ion generating device 120 is opened and water is supplied into the storage container 122 together with the water supply operation. When power is applied to the two silver plates 220 and 222 of the ion generating device 120, silver solution sterilized water is prepared. This silver solution sterilizing water is supplied into the washing tank 106 to sterilize the laundry.

That is, the water supplied through the inlet 202 of the storage container 122 is first filled in the first space 210 of the storage container 122 and rectified to stabilize the flow rate and flow, and the water of the first space 210. It flows beyond this 1st partition 206 to the 2nd space 214. As shown in FIG. The water flowing into the second space 214 after passing through the first space 210 is filled in the second space 214 at a level corresponding to the height of the second partition 208, and the second space 214 is filled with water. After the water is filled, the third space 224 flows beyond the second partition 208 and is supplied into the washing tank 106 through the outlet 216. At this time, the water of the second space 214 is gradually flowed toward the third space 224 while maintaining a certain amount of fresh water. In this process, silver solution sterilized water is prepared through electrolysis of the two silver plates 220 and 222. The prepared sterilized water is supplied to the washing tank 106 through the outlet 216. This sterilization water production operation is continuously performed during the water supply.

In addition, when there is a lot of water supplied to the inlet 202 in the process of manufacturing the sterilization water because the water inside the storage container 122 flows toward the drain pipe 118a through the discharge pipe 128, the interior of the storage container 122 It can be maintained at an appropriate level, it is possible to always produce a constant concentration of silver solution sterilized water. In addition, when the sterilizing water production operation is completed, the inlet valve 204 is closed to stop the water supply to the storage container 122 and at the same time, the power supply to the two silver plates 220 and 222 is also stopped. At this time, the remaining water flows toward the outlet 216 through the remaining water discharge holes 206a and 208a under the two partitions 206 and 208 and is completely discharged.

After the wash water including the sterilizing water is filled in the water tank 104, the pulsator 108 is rotated to wash the laundry, and bacteria are sterilized by the sterilizing water during the washing.

The ion generating device 120 generates silver ions by electrolyzing in water by alternately applying voltages of positive and negative polarities to the two silver plates 220 and 222. At this time, the amount of silver ions generated, that is, the concentration of the silver solution, is proportional to the amount of current flowing through the two silver plates 220 and 222 or the magnitude of the voltage applied to the two silver plates 220 and 222.

3 is a block diagram showing a control system of the washing machine shown in FIG. As shown in FIG. 3, the driving unit 302 alternately applies voltages of (+) polarity and (−) polarity to the ion generator 120 so that the silver solution is manufactured. The polarity of the voltage applied to the ion generator 120 from the driver 302 is controlled by the first and second switching signals 316 and 318 output from the controller 306 to the driver 302.

In FIG. 3, the comparator 310 generates a current amount decrease signal 320 (first current signal) when the magnitude of the driving current 324 detected by the current detector 308 is very close to zero or zero, thereby controlling the controller 306. Will output If the magnitude of the driving current 324 of the driving unit 302 is very close to zero or zero, the control unit 306 may have a poor coupling state of the silver plates 202 and 222, a disconnection of the power line, and complete consumption of the silver plates 220 and 223. It is determined by the display unit 350 to display it so that the user can check it. In this case, it is more preferable to notify the user by generating an alarm as necessary and to temporarily stop the operation of the washing machine.

FIG. 4 is a circuit diagram showing a driver of the ion generating device shown in FIG. 1. As shown in Fig. 4, npn bipolar transistors 402 and 404 constitute one series circuit between power supply voltage VCC and ground GND. In parallel with this series circuit, the npn bipolar transistors 406 and 408 constitute another series circuit.

The npn bipolar transistors 402, 408 are controlled by the first switching signal 316, and the npn bipolar transistors 404, 406 are controlled by the second switching signal 318. The first control voltage 326 output between the npn bipolar transistors 402 and 404 is applied to one of the two silver plates 220 and 222 of the ion generating device 120. The second control voltage 328 output between the npn bipolar transistors 406 and 408 is applied to the other of the two silver plates of the ion generating device 120. In FIG. 4, the emitter currents of the npn bipolar transistors 404 and 408 are the driving currents 324 which are the total currents flowing in the driver 302, and are detected by the current detector 308 mentioned in the description of FIG. 3. Supplied to the comparator 310.

5 is a flowchart illustrating a control method of an ion generating device according to an embodiment of the present invention. As shown in FIG. 5, after performing electrolysis for generating silver ions (502), it is checked whether the magnitude of the driving current 324 which is the total current flowing through the driving unit 302 is 0 or very close to 0 (504). . If the magnitude of the driving current 304 is very close to 0 or 0, the display current is displayed through the display unit 350 so that the user may have a poor coupling state of the silver plates 202 and 222 or a disconnection of the power line, and the silver plates 220 and 223. ) To recognize the possibility of complete consumption and to stop the electrolysis (506). If the magnitude of the driving current 304 is zero or very close to zero in the state of electrolysis in progress, electrolysis is performed until the electrolysis setting time elapses (508). In other words, it monitors whether the electrolysis setting time has elapsed since the start of electrolysis, and then ends the electrolysis when the electrolysis setting time elapses.

Such an ion generating device according to the present invention can be utilized in all products using the ion generating device as well as the washing machine mentioned above.

The control method of the ion generating device according to the present invention detects and displays a poor state of bonding of metals to generate ions, disconnection of power lines, and complete consumption of metals, thereby allowing a user to check and take action.

Claims (4)

In the control method of the ion generating device for generating ions through electrolysis of metal, Applying a control voltage for electrolysis to the ion generating device to generate ions according to electrolysis in the ion generating device; Detect a magnitude of a drive current flowing through the metal as the control voltage is applied; And determining that the electrolysis is not performed in the ion generating device when the magnitude of the driving current decreases to a preset size and displaying the same through the display unit. The method of claim 1, And if it is determined that electrolysis is not performed, stopping the supply of the control voltage to stop the electrolysis. The method of claim 1, And the preset value is 0 amperes (A). The method of claim 1, And stopping electrolysis when the state in which the drive current maintains the predetermined value or more continues for a predetermined time or more.

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