KR20040090863A - Disinfection washing machine and control method thereof - Google Patents

Abstract

PURPOSE: A sterilization washing machine and a control method thereof are provided to sterilize the laundry efficiently, and to prevent pollution of the laundry by regulating the voltage applied to silver plates according to the density of silver ions. CONSTITUTION: A washing machine comprises a sterilization water supply apparatus(304) supplying sterilization water for sterilizing the laundry; a driving unit(302) generating and outputting first voltage and second voltage for deciding the density of sterilization water to the sterilization water supply apparatus; comparators(310,312) deciding the density of sterilization water to be within the predetermined range; and a control unit(306) controlling the driving unit to adjust the density of sterilization water within the predetermined range according to output from the comparators. Silver ions for sterilization is generated through the electrolysis by applying first voltage and second voltage to two silver plates.

Description

Sterilization washing machine and its control method {DISINFECTION WASHING MACHINE AND CONTROL METHOD THEREOF}

The present invention relates to a washing machine, and more particularly, to a sterilizing washing machine having a sterilizing water supply device for sterilizing laundry.

The sterilizing washing machine includes ozone and silver ions. Among them, the sterilizing washing machine using silver solution supplies sterilizing water which manufactures and supplies silver solution to sterilize laundry through antibacterial and sterilizing action of silver solution. It is a washing machine adopting a device.

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.

The bactericidal effect by the silver solution is determined by the concentration of the silver solution. In other words, if the concentration of the silver solution is too low, the sterilization effect is lowered. On the contrary, if the concentration of the silver solution is too high, the silver solution discolors the laundry. Therefore, the concentration of the silver solution should be properly adjusted so as not to contaminate the laundry while obtaining a sufficient bactericidal effect. In order to prepare an appropriate solution of silver, the voltage applied to the silver plate of the silver ion generating device must be adjusted to an appropriate range.

The sterilizing washing machine according to the present invention adjusts the magnitude of the voltage applied to the silver plate when the concentration of the current silver solution is out of a predetermined range, so that the sterilization effect has a silver ion concentration within a suitable range without contaminating the laundry. The purpose is.

1 is a cross-sectional view showing a sterilizing washing machine according to the present invention.

Figure 2 is a sectional view showing a sterilizing water supply device provided in the sterilizing washing machine according to the present invention.

Figure 3 is a block diagram showing a silver solution concentration control device provided in the sterilizing washing machine according to the present invention.

4 is a circuit diagram showing a driving unit of the silver solution concentration control apparatus according to the present invention.

5 is a view showing waveforms of signals applied to a driving unit of the silver solution concentration control apparatus according to the present invention.

Figure 6 is a flow chart illustrating a method for controlling the silver solution concentration of the sterilizing washing machine according to the present invention.

Sterilizing washing machine according to the present invention for this purpose comprises a sterilizing water supply device, a drive unit, a control unit. The sterilizing water supply device is for supplying sterilizing water for sterilizing laundry. The sterilizing water supplied through this sterilizing water supply device maintains an appropriate concentration so as not to contaminate the laundry while generating a sufficient sterilizing effect. The control unit detects the concentration of the sterilizing water and controls the driving unit so that the concentration of the sterilizing water has a value within a preset range. The driving unit controls the concentration of the sterilizing water of the sterilizing water supply device by outputting the first and second control voltages of appropriate levels under the control of the controller.

A preferred embodiment of the sterilizing washing machine and its control method according to the present invention will be described with reference to FIGS. 1 to 6.

1 is a cross-sectional view showing a sterilizing washing machine according to 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.

2 is a cross-sectional view showing a sterilizing water supply apparatus of the sterilizing washing machine according to the present invention. As shown in Figure 2, laundry is put into the sterile washing machine, and when the washing course is set after power is supplied, the 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 sterilizing water supply 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 sterilizing water supply device 120, silver solution sterilizing 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 manufactured through electrolysis of the two silver plates 220 and 222, and The 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 sterilization water supply device 120 generates silver ions by electrolyzing in the water by alternately applying voltages of (+) and (-) 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.

Figure 3 is a block diagram showing a silver solution concentration control device provided in the sterilizing washing machine according to the present invention. As shown in FIG. 3, the driving unit 302 alternately applies voltages of (+) polarity and (−) polarity to the sterilizing water supply device 304 so that the silver solution is manufactured. The polarity of the voltage applied from the driver 302 to the sterilizing water supply device 304 is controlled by the first and second switching signals 316 and 318 output from the controller 306 to the driver 302.

The amount of current supplied to the sterilizing water supply device 304 is proportional to the magnitude of the applied voltage, and the applied voltage can be estimated through the driving current 324 flowing through the driver 302. The control unit 306 is the first and second switching signal (316, 318) if the magnitude of the drive current 324 of the drive unit 302 exceeds the upper limit of the range capable of producing a silver solution of the appropriate concentration required for sterilization of the laundry. ) Is temporarily stopped to prevent the generation of silver ions. Conversely, if the magnitude of the drive current 324 is reduced below the lower limit, appropriate protection measures are taken accordingly. The shortage of the driving current 324 means that water is not supplied through the sterilizing water supply device 304 or at least the amount of water is insufficient, and that the coupling state of the silver plates 202 and 222 is poor or the power line is disconnected. do. Therefore, when the size of the drive current 324 of the drive unit 302 is reduced below the lower limit, an alarm is generated to inform the user and to suspend the operation of the sterilizing washing machine.

When the magnitude of the driving current 324 detected by the current detector 308 exceeds a preset upper limit, the first comparator 312 generates the current amount exceeding signal 320 and outputs it to the controller 306. The controller 306 prevents at least one of the first switching signal 316 and the second switching signal 318 from being applied when the current amount exceeding signal 320 is generated in the first comparator 312 so that the sterilizing water supply device The generation of silver ions at 304 is stopped. When generation of silver ions is stopped in the state where water is supplied to the sterilizing water supply device 304, the concentration of silver ions in the sterilizing water drops.

When the magnitude of the driving current 324 detected by the current detector 308 decreases below the preset lower limit, the second comparator 310 generates a current shortage signal 322 and outputs it to the controller 306. The controller 306 generates an alarm when a current shortage signal 322 is generated in the second comparator 310 to notify the user of the alarm and temporarily suspends the operation of the sterilizing washing machine.

The configuration of the driving unit 302 for controlling the silver solution concentration of the sterilizing water supply device 304 will be described with reference to FIGS. 4 and 5 as follows. 4 is a circuit diagram showing a driving unit of the silver solution concentration control apparatus according to the present invention. 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 sterilizing water supply 304. 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 sterilizing water supply 304. 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 first and second comparators 312 and 310.

5 is a view showing waveforms of signals applied to a driving unit of the silver solution concentration control apparatus according to the present invention. As shown in Fig. 5, the phases of the first and second switching signals 316 and 318, which are input signals, are opposite to each other. However, there is some dead time t _d at each transition point of the first and second switching signals 316 and 318. When the first and second switching signals 316 and 318 simultaneously transition, a section in which the two signals overlap is generated. In this case, the two silver plates 220 and 222 of the sterilizing water supply device 304 are electrically shorted to each other. Placing the four sections t _d between transition points of the first and second switching signals 316 and 318 can prevent the two silver plates 220 and 222 of the sterilizing water supply device 304 from being electrically shorted to each other. have.

As with the first and second switching signals 316 and 318, the phases of the first and second control voltages 326 and 328 as output signals are also opposite to each other. The phase of the first control voltage 326 is the same as the phase of the first switching signal 316, and the phase of the second control voltage 328 is the same as the phase of the second switching signal 318.

The operation of the driving unit 302 for controlling the silver solution concentration of the sterilizing water supply device 304 will be described with reference to FIGS. 4 and 5 as follows. In FIG. 5, when the first switching signal 316 is high level and the second switching signal 318 is low level, only npn bipolar transistors 402 and 408 of FIG. 4 are turned on so that the power supply voltage VCC is npn bipolar transistor ( 402, sterile water supply 304 and npn bipolar transistor 408 flow to ground GND. At this time, voltage is applied to the two silver plates 220, 222 of sterile water supply 304. The first control voltage 326 is of positive polarity and the second control voltage 328 is of negative polarity.

The npn bipolar transistors 406 and 404 of FIG. 4 when the phases of the first and second switching signals 316 and 318 are reversed so that the first switching signal 316 is low level and the second switching signal 318 is high level. Only the turn-on of the power supply voltage (VCC) flows to the ground (GND) through the npn bipolar transistor 406, the sterile water supply device 304, the npn bipolar transistor 404. At this time, a voltage is applied to the two silver plates 220 and 222 of the sterilizing water supply device 304. The first control voltage 326 is changed to the negative polarity and the second control voltage 328 is the positive polarity. Change.

As such, the first and second control voltages 326 and 328 output from the driver 302 to the sterilizing water supply device 304 alternately invert polarities with each other by the first and second switching signals 316 and 318. do. Since the first and second control voltages 316 and 318 are voltages applied to the two silver plates of the sterilizing water supply device 304, the first and second control voltages 326 and 328 are used in the sterilizing water supply device 304. Silver solution is made during this feed.

6 is a flowchart illustrating a method for controlling silver solution concentration of a sterilizing washing machine according to the present invention. As shown in FIG. 6, when the sterilization washing mode is started 602, the first and second switching signals 316, 318 are applied to generate the first and second control voltages 326, 328 (604). . At this time, the driving current 324 flowing through the driving unit 302 is detected and compared through the first and second comparators 320 and 322 so that the driving current 324 is set in the upper limit I _max and lower limit I _min . It is determined whether the range is between (608).

If the magnitude of the driving current 324 is within the range between the upper limit I _max and the lower limit I _min (610), the first and second switching signals 316 and 318 are continuously applied (612), and the set washing is performed. After the administration time elapses, the washing is terminated (614). When the magnitude of the driving current 324 exceeds the upper limit I _max (616), the application of the first and second switching signals 316 and 318 is stopped so that the concentration of the silver solution no longer increases and the driving current ( The process returns to step 610 of monitoring whether 324 is within a set range (618). When the magnitude of the driving current 324 decreases below the lower limit I _min (620), an alarm is generated and the operation of the washing machine is stopped (622). As such, the controller 306 of the sterilizing washing machine according to the present invention monitors the amount of current flowing between the two silver plates of the sterilizing water supply device 304, thereby detecting whether the silver solution currently generated has a concentration within an appropriate range. If necessary, the silver solution is controlled so that it is out of the proper range.

The present invention controls the magnitude of the voltage applied to the silver plate according to the current concentration of the silver solution so that the silver solution can provide a sufficient sterilizing effect while maintaining the concentration within an appropriate range without contaminating the laundry.

Claims (9)

In the washing machine, A sterilizing water supply device for supplying sterilizing water for sterilizing laundry; A driving unit generating first and second control voltages for determining the concentration of the sterilizing water and outputting the first and second control voltages to the sterilizing water supply device; A comparator for determining whether the concentration of the sterilizing water is within a preset range; And a controller configured to control the driving unit so that the concentration of the sterilizing water has a value within a preset range according to the output of the comparator. The method of claim 1, The sterilizing water is a washing machine is a silver solution made by applying the first and second control voltage to the at least two silver plate provided in the sterilizing water supply, respectively, by electrolysis. The method of claim 2, And a concentration of the silver solution is determined according to the levels of the first and second control voltages. The method of claim 1, A current detector for detecting an amount of current supplied from the driver to the sterilizing water supply device; And the control unit determines the concentration of the sterilizing water through the amount of current detected by the current detection unit. The method of claim 1, A first comparator for outputting an excess current amount signal to the controller when the amount of current supplied from the driver to the sterilizing water supply device is greater than a preset upper limit; A second comparator for outputting a current shortage signal to the controller when the amount of current supplied from the driver to the sterilizing water supply device is smaller than a preset lower limit; The control unit is a washing machine to control the driving unit to reduce the concentration of the sterilizing water when the current amount excess signal is generated, and generates an alarm when the current amount shortage signal occurs. The method of claim 1, wherein the driving unit, A high level and a low level are repeatedly alternated, and receive first and second switching signals having opposite phases; And a first and a second switching circuit for outputting first and second control voltages of opposite phases to each other through the first and second switching circuits. The method of claim 6, The first and second switching circuits are alternately turned on by the first and second switching signals so that the first and second control voltages have the same phase and period as the first and second switching signals. . A sterilizing water supply apparatus for supplying sterilizing water for sterilizing laundry, and a control method of a washing machine including a driving unit generating first and second control voltages for determining the concentration of the sterilizing water and outputting the sterilizing water to the sterilizing water supply device. To Determining a magnitude of a driving current generated in the driving unit according to the first and second control voltages; Continuously generating the first and second control voltages when the magnitude of the drive current is within a preset range; The control method of the washing machine to stop the operation of the washing machine when the drive current is out of the setting range. The method of claim 8, Stopping generation of the first and second control voltages when the drive current exceeds an upper limit of the set range; A control method of the washing machine, which generates an alarm and stops the operation of the washing machine when the driving current decreases below the lower limit of the setting range.