JP4955844B2 - Alkaline ion water conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to an alkali ion water conditioner that electrolyzes raw water such as tap water to produce alkaline ionized water used for drinking and medical use, and acidic ionized water used as a lotion or sterilizing washing water. It is.
[0002]
[Prior art]
In recent years, alkali ion water conditioners have become widespread as continuous electrolysis type ion water generators. This alkaline ion adjuster electrolyzes tap water or the like in an electrolytic cell to generate acidic ion water on the anode side and alkaline ion water on the cathode side.
[0003]
Hereinafter, a control method of a conventional continuous electrolysis type alkaline ion water conditioner will be described. Flow rate input means for inputting the flow rate flowing into the alkaline ionized water device with a flow rate sensor, etc., electrolytic voltage output means for outputting a voltage (hereinafter referred to as electrolysis voltage) applied to the electrolytic cell for electrolyzing the raw water, and flowing to the electrolytic cell PH value of alkaline ionized water or acidic ionized water (hereinafter referred to as ionic water) generated by applying an electrolytic voltage with electrolytic current input means for inputting current (hereinafter referred to as electrolytic current), raw water or electrolytic voltage output means The flow rate of the pH sensor to be detected and the flow rate input means determines which level (hereinafter referred to as flow rate level) divided into q (q is an arbitrary number) the range of flow rates that can be generated, and the electrolytic voltage Control means (hereinafter referred to as MPU) for judging the electrolytic voltage to be output to the output means, calculating the data, inputting / outputting data, etc., setting p for inputting the pH value to be generated by a switch etc. In the configuration of the input operation means, the storage means for storing the data such as the electrolysis current and the electrolysis voltage for each flow rate level at each pH value, and the alarm means for notifying the malfunction with an LED, a buzzer, etc. Corresponds to the pH value set by the set pH input operation means (hereinafter, set pH value) and the flow level of the water flow when the flow rate input by the flow rate input means is greater than the arbitrary flow rate of the storage means (hereinafter referred to as water flow) When the electrolytic voltage stored in the storage means is applied, a control method is adopted in which the electrolytic voltage is varied so that the pH value input from the pH sensor (hereinafter, input pH value) matches the set pH value. .
[0004]
[Problems to be solved by the invention]
As described above, in the conventional technology, bubbles generated in a water passage or the like during electrolysis rarely adhere to the pH sensor, and the pH sensor detects an incorrect pH value, or the pH sensor malfunctions for some reason. In some cases, there is a problem that ion water having a pH value different from the set pH value may be generated and provided.
[0005]
Therefore, the present invention can always generate ion water having a stable set pH value even when the control means determines that the input pH value from the pH sensor is abnormal because it is not within a predetermined range of the set pH value. An object of the present invention is to provide an alkaline ionized water device capable of prompting a warning to promptly clean and calibrate or replace a pH sensor when the control means determines that the sensor is defective.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides flow rate input means for inputting a flow rate detected by a flow sensor, electrolytic voltage output means for outputting a voltage applied to the electrolytic cell for electrolysis, and an electrolytic cell. The electrolytic current input means for inputting the electrolytic current value of the flowing current, and the pH value of the ionic water generated by applying the electrolytic voltage with the raw water or the electrolytic voltage output means are detected. And enter the pH value as the input pH value. The flow rate level is determined from the pH sensor to be input and the flow rate input by the flow rate input means, the electrolytic voltage value of the electrolytic voltage to be output to the electrolytic voltage output means is determined with respect to the flow level, the timer, and the data calculation and data Control means to input and output the pH value of the ion water to be generated As the set pH value When the set pH input operation means that is input by a switch and the range of flow rates that can be generated are divided into arbitrary numbers, the flow rate level for each set pH value set by the set pH input operation means is used as a reference. Measure the electrolysis current value and electrolysis voltage value when the input pH value detected and input by the pH sensor of ionic water generated by electrolyzing raw water enters the specified range of each set pH value, and set each pH value Storage means for storing an electrolytic current value and an electrolytic voltage value for each flow rate level The An alkali ion water conditioner, When generating ionized water having a set pH value set by the set pH input operation means, the set pH value set by the set pH input operation means and the electrolytic voltage of the electrolysis voltage value stored in the storage means at the flow rate level at that time are set. When the input pH value detected by the pH sensor is applied to the electrolytic cell and the pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means, the input pH detected by the pH sensor is A control method is performed in which the electrolysis voltage is varied so that the value falls within a predetermined range of the set pH value set by the set pH input operation means, and the pH sensor is detected after the predetermined time has elapsed. The input pH value is Set by pH input operation means Set pH value default If the control means determines that the current is not within the range, the electrolytic current value input by the electrolytic current input means is Set by pH input operation means The electrolysis voltage is varied so that it is within a certain range of the electrolysis current value stored in the storage means at the set pH value and the flow rate level at that time. Distinct The control method was performed.
[0007]
With this configuration, the input pH value from the pH sensor is equal to the set pH value. default Therefore, even if the control means determines that it is abnormal because it is not within the range, it is possible to provide an alkali ion water conditioner that can always generate ion water having a stable set pH value.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
According to the first aspect of the present invention, flow rate input means for inputting a flow rate detected by a flow rate sensor, electrolytic voltage output means for outputting a voltage applied to the electrolytic cell for electrolysis, and electrolysis of a current flowing in the electrolytic cell. Detects the pH value of the electrolysis current input means for inputting the current value and the pH value of the ionic water generated by applying the electrolysis voltage with raw water or the electrolysis voltage output means And enter the pH value as the input pH value. The flow rate level is determined from the pH sensor to be input and the flow rate input by the flow rate input means, the electrolytic voltage value of the electrolytic voltage to be output to the electrolytic voltage output means is determined with respect to the flow level, the timer, and the data calculation and data Control means to input and output the pH value of the ion water to be generated As the set pH value When the set pH input operation means that is input by a switch and the range of flow rates that can be generated are divided into arbitrary numbers, the flow rate level for each set pH value set by the set pH input operation means is used as a reference. Measure the electrolysis current value and electrolysis voltage value when the input pH value of ionic water generated by electrolyzing raw water falls within the specified range of each set pH value, and the electrolysis current value for each flow rate level at each set pH value And storage means for storing the electrolytic voltage value The An alkali ion water conditioner, When generating ionized water having a set pH value set by the set pH input operation means, the set pH value set by the set pH input operation means and the electrolytic voltage of the electrolysis voltage value stored in the storage means at the flow rate level at that time are set. When the input pH value detected by the pH sensor is applied to the electrolytic cell and the pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means, the input pH detected by the pH sensor is A control method is performed in which the electrolysis voltage is varied so that the value falls within a predetermined range of the set pH value set by the set pH input operation means, and the pH sensor is detected after the predetermined time has elapsed. The input pH value is the set pH value. default If the control means determines that the current is not within the range, the electrolytic current value input by the electrolytic current input means is Set by pH input operation means The electrolysis voltage is varied so that it is within a certain range of the electrolysis current value stored in the storage means at the set pH value and the flow rate level at that time. Distinct The control method is performed.
[0009]
In this configuration, when the range of flow rates that can be generated is divided into arbitrary numbers, Set by pH input operation means Measure the electrolysis current value and electrolysis voltage value when the input pH value of the ionic water generated by electrolyzing the reference raw water falls within a predetermined range of the set pH value at all flow levels for each set pH value, The storage means stores the electrolytic current value and electrolytic voltage value for each flow rate level at each set pH value. Every , When generating ionic water of the set pH value set by the set pH input operation means, it was set by the set pH input operation means. Apply the electrolytic voltage of the electrolytic voltage value stored in the storage means at the set pH value and the flow rate level at that time to the electrolytic cell, and after a predetermined time, When the input pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means, it is detected by the pH sensor. Input pH value is Set by pH input operation means The electrolytic voltage is varied so as to be within a predetermined range of the set pH value. Detected by pH sensor after the predetermined time The input pH value is the set pH value. default If the MPU determines that the current is not within the range, the electrolytic current value input by the electrolytic current input means is Set by pH input operation means Switching to a control method for generating ionic water of the set pH value by varying the electrolysis voltage so that it is within a certain range of the electrolysis current value stored in the storage means at the set pH value and the flow rate level at that time Thus, even when the MPU determines that the input pH value from the pH sensor is abnormal, it is possible to always generate ion water having a stable set pH value.
[0010]
According to the second aspect of the present invention, the set pH value when the input pH value falls within the predetermined range of the set pH value, and the electrolytic current value and the electrolytic voltage value at the flow rate level at that time are updated and stored in the storage means. By switching to the control method to be performed, it is possible to always generate ion water having a stable set pH value.
[0011]
According to the third aspect of the present invention, the input pH value during the electrolysis is the set pH value. default If the control means determines that it is abnormal because it is not within the range of water, and the control means determines that the input pH value is abnormal by continuously passing water again and the pH value is abnormal. When the control means determines that the sensor is defective and notifies the alarm means, it is possible to promptly request cleaning and calibration or replacement of the pH sensor.
[0012]
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic structural diagram of an alkaline ionized water device according to an embodiment of the present invention, FIG. 2 is a block diagram showing a configuration of a main control unit of the alkaline ionized water device, and FIG. 3 is an alkaline ionized water device. FIG. 4, FIG. 5, and FIG. 6 are flowcharts of the control of the alkaline ionized water device.
[0013]
4 to 6 show the settable pH values (P ₀ To P _p Flow rate level (Q) ₀ To Q _q ) In all cases, the electrolytic current value I when the input pH value of the ionic water generated when the raw water as a reference is electrolyzed in advance falls within a predetermined range of the set pH value. _PiQj And electrolytic voltage V _PiQj (0 ≦ i ≦ p, 0 ≦ j ≦ q) is measured, and the set pH value (P ₀ To P _p Flow level (Q) ₀ To Q _q ) Is stored in the storage means as matrix data of the electrolytic current value and the electrolytic voltage value, and when the MPU determines that the input pH value is normal during electrolysis, the input pH value is brought close to the set pH value. When the electrolytic voltage is varied and applied to the electrolytic cell, the electrolytic current value when the input pH value falls within the predetermined range of the set pH value, and the electrolytic voltage value at the flow rate level at the set pH value and the electrolytic voltage If the MPU determines that the input pH value is abnormal when the corresponding location is updated and stored in the storage means as matrix data of values, the electrolysis of the flow level at the corresponding set pH value stored by the input electrolysis current value Flow chart of a control method for generating ionized water having a set pH value by varying the electrolysis voltage so as to fall within a certain range of current value, and input input from a pH sensor during electrolysis If the control means determines that the input pH value input from the pH sensor is normal again after the control means determines that the H value is abnormal, the input pH value input from the pH sensor is brought close to the set pH value. Therefore, the electrolytic voltage is applied to the electrolytic cell while varying the electrolysis voltage, and the electrolysis current value when the input pH value input from the pH sensor enters the predetermined range of the set pH value, and the electrolysis voltage value of the flow level at the set pH value. As a matrix data of the electrolysis current value and the electrolysis voltage value, a flowchart of a control method in which the corresponding part is updated and stored in the storage means, and further, if the input pH value input from the pH sensor during electrolysis is abnormal, the control means When the control means determines that the input pH value input from the pH sensor is abnormal after stopping the water in the state determined by And the control means is defective pH sensor is indicative a flow chart of a control method for notifying the decision to warning means.
[0014]
In FIG. 1, 1 is a raw water pipe such as tap water, 2 is a faucet, 3 is an alkali ion water regulator connected to the raw water pipe 1 through a faucet 2, and 4 absorbs residual chlorine in the raw water inside. Purifying part equipped with activated carbon and hollow fiber membrane for removing general bacteria and impurities, 5 is a flow rate sensor as a flow rate input means for instructing control of water flow to the control means described later, 6 is calcium such as calcium glycerophosphate and calcium lactate Calcium supply section for imparting ions to the raw water to increase the conductivity, 7 is an electrolytic cell that electrolyzes the water that has passed through, 8 is a diaphragm that forms an electrolytic chamber that divides the electrolytic cell in two, and 9 and 10 are diaphragms 8 Electrode plates disposed in each electrolysis chamber divided into two parts, 11 is a solenoid valve for draining washing water, 12 is a discharge pipe for discharging water on the electrode plate 9 side, 13 is raw water or generated PH sensor for detecting the pH value of the deionized water, 4 is a control means such as an MPU that controls the operation of the alkaline ionized water conditioner, 15 is a power-on plug, 16 is a power supply unit that converts an alternating current from the power-on plug 15 into a direct current, and 17 is an alkaline ion regulator. Storage means for storing information on the operation of the water device, 18 is a drain pipe for discharging water on the electrode plate 10 side, 19 is a set pH input operation means for setting a pH value to be generated by the alkali ion water conditioner 3, and 20 Is an alarm means for notifying abnormality of an alkaline ionized water conditioner, 21 is an electrolytic voltage output means for applying an electrolytic voltage to the electrolytic cell 7, and 22 is a result of applying an electrolytic voltage to the electrolytic cell 7 by the electrolytic voltage output means 21 Electrolytic current input means 23 for instructing the control means 14 to control the electrolytic current flowing in the electrolytic cell 7, and 23 is an electrolysis promoter supply section.
[0015]
Next, the operation | movement which produces | generates ionic water is demonstrated about the alkaline ionized water apparatus comprised as mentioned above. The user selects the pH value of alkaline ion water or acidic ion water to be generated by the set pH input operation means 19. Then, the faucet 2 is opened. The raw water passed through the faucet 2 removes residual chlorine and impurities from the raw water at the water purification unit 4, confirms the amount of water flow through the flow sensor 5, and dissolves calcium glycerophosphate and the like at the calcium supply unit 6 to facilitate electrolysis. Then, an electrolysis promoter such as salt water is added at the electrolysis promoter supply unit 23 and water is passed through the electrolysis tank 7.
[0016]
On the other hand, AC 100 V is supplied from the power-on plug 15 and converted into a control DC power source by the power source unit 16. When a positive voltage and a negative voltage are relatively applied to the electrode plates 9 and 10 partitioned by the diaphragm 8 in the electrolytic cell 7, an anode chamber and a cathode chamber are formed, respectively. At this time, alkaline ionized water is generated on the cathode chamber side and acidic ionized water is generated on the anode chamber side.
[0017]
Now, when water is passed through the alkali ion water conditioner 3, the flow rate sensor 5 and the control means 14 determine that the water is flowing. At this time, since the electrolysis conditions are set by the set pH input operation means 19, the control means 14 applies an electrolysis voltage to the electrode plates 9 and 10 via the electrolysis voltage output means 21 in order to perform electrolysis in the electrolytic cell 7. To do. As a result, the set ionic water is discharged to the water discharge pipe 12.
[0018]
Further, when the flow rate input by the alkali ion water conditioner 3 with the flow rate sensor 5 is less than the predetermined flow rate of the storage means (hereinafter referred to as water stoppage), the polarity of the voltage is reversed when a certain cleaning condition is satisfied. The electrode plates 9 and 10 are washed by application. And after completion | finish of washing | cleaning, the solenoid valve 11 is opened and washing water is discharged | emitted from the drain pipe 18. FIG.
[0019]
Next, the main block diagram of the control method of the alkaline ionized water device 3 of the present invention shown in FIG. 2 will be described. RAM for storing data (variable number), storage means including EEPROM for storing retained data even when the power is turned off, 5 is a flow rate input means capable of detecting a flow rate such as a flow rate sensor, and 21 is electrolyzed Electrolytic voltage output means such as FET for outputting the voltage applied to the electrolytic cell for the purpose, 22 is an electrolytic current input means for inputting the current flowing through the electrolytic cell, 13 is the result of applying the electrolytic voltage with raw water or electrolytic voltage output means, A pH sensor 14 for detecting the pH value of the generated ionic water determines the flow level from the flow rate of the flow rate input means, determines the electrolysis voltage of the electrolysis voltage output means, determines the timer, MPU that performs data calculation and data input / output, 19 is a set pH input operation means for setting the pH value of ionic water to be generated, 20 is an alarm means for notifying the malfunction of the pH sensor 13 by a display or buzzer, etc., and 23 is purification It is an electrolysis promoter supply part which adds electrolysis promoters, such as salt water, to the dried water.
[0020]
3 to 6, when the set pH value that can be set by the set pH input operation means is divided into p levels and the flow rate is divided into q levels (p and q are arbitrary numbers), any setting within the settable range is possible. pH value (hereinafter P _i (0.ltoreq.i.ltoreq.p: i and p are arbitrary numbers))), the time from application of the electrolysis voltage to the start of variable electrolysis voltage (hereinafter referred to as T1), counter Initialization (hereinafter, initial setting 1) such as X = 0, Y = 0, Z = 0, S = 0 is performed (step 1). The minimum flow rate level (hereinafter, Q ₀ ) It is determined whether or not (step 2). Q ₀ If not, the output of the electrolysis voltage is stopped and the process ends. Q ₀ If it is above, the flow level is Q _j (0 ≦ j ≦ q: j and q are arbitrary numbers), P stored in the storage means _i Flow level Q at _j Electrolysis voltage (hereinafter, V ' _PiQj ) Is applied to the electrolytic cell (hereinafter, initial setting 2) (step 3). If the initial setting 2 has been completed, the electrolysis voltage during control (hereinafter referred to as V _PiQj ) Is applied to the electrolytic cell (step 4). If the initial setting 2 has not been completed, the initial setting 2 is performed and the process jumps to step 6 (step 5).
[0021]
Next, an electrolytic current (hereinafter, I _PiQj (Step 6). T after starting electrolysis ₁ It is determined whether the time has elapsed (step 7). If not, it is determined whether the corresponding matrix data has been updated in the past (step 9). If it has been updated, the process returns to Step 2. If not updated, the process jumps to step 36.
[0022]
T in step 7 ₁ If it has elapsed, the pH value of the ionic water is input with the pH sensor (step 8). Input pH value is P _i ± m ₂ (M ₂ Is within an arbitrary number range (step 10). If not, jump to step 27. If it is within the range, the input pH value is P _i ± m ₁ (M ₁ Is within an arbitrary number range (step 11). If it is not within the range, the process jumps to step 19. If it is within the range, the counter Z is set to 0, and it is determined whether or not the electrolytic voltage control is performed by the pH sensor (step 12). If the electrolytic voltage is controlled by the pH sensor, the counter S is incremented by 1 (step 13). And the electrolytic voltage control by pH sensor is n ₂ (N ₂ Is determined to be continuous (arbitrary number) times (step 14). If not continuous, return to Step 2. If continuous, V in control _PiQj , I _PiQj V ' _PiQj , I ' _PiQj Are updated and stored in the storage means (step 15). If the electrolytic voltage is not controlled by the pH sensor in step 10, the counter X is incremented by 1 (step 16). X is n ₁ (N ₁ Is an arbitrary number) (step 17). X is n ₁ Otherwise, return to step 2. X is n ₁ If so, the electrolytic voltage is controlled by the pH sensor, the counter Y is set to 0, and the process returns to step 2 (step 18).
[0023]
The input pH value input in step 11 is P _i ± m ₁ (M ₁ Is not within the range), the counter S = 0 and the input pH value is P _i It is determined whether it is larger (step 19). V is larger _PiQj Subtract n (n is an arbitrary number) from (step 20). That V _PiQj Is the minimum electrolysis voltage (V _min It is determined whether or not the following is true (step 21). V _min V if _PiQj = V _min (Step 22). V _min If not, return to Step 2. The input pH value input in step 19 is P _i It is determined whether it is smaller (step 23). If not, return to Step 2. V is small _PiQj N (n is an arbitrary number) is added to (step 24). That V _PiQj Is the maximum electrolysis voltage (V _max It is determined whether or not the above is true (step 25). V _max V above _PiQj = V _max (Step 26).
[0024]
The input pH value input in step 10 is P _i ± m ₂ (M ₂ If it is not within the range of (arbitrary number), the counter S = 0 and it is determined whether or not the electrolytic voltage control is by the pH sensor (step 27). If the electrolytic voltage is controlled by the pH sensor, the counter Y is incremented by 1 (step 28). Y is n _Three (N _Three Is an arbitrary number) (step 29). Y is n _Three Otherwise, return to step 2. Y is n _Three If so, the counter Z is incremented by 1 (step 30). Z is n _Four (N _Four Is an arbitrary number) (step 31). Z is n _Four If so, it is determined whether or not it has occurred again after the cleaning and calibration after the pH sensor cleaning and calibration request (step 32). After the cleaning calibration request, if it occurs after cleaning and calibration of the pH sensor, it is determined that the pH sensor has failed, the alarm means for requesting replacement is set (step 33), and after the cleaning calibration request, the pH sensor is set. If it does not occur after cleaning and calibration of the sensor, it is determined that the problem is due to contamination of the pH sensor, a shift in the asymmetry potential, etc., and alarm means that require cleaning and calibration of the pH sensor are set. Is stopped and finished (step 34). In step 31, Z is n _Four Otherwise I ' _PiQj Switch to the electrolysis voltage control according to, set X to 0 and return to step 2 (step 35).
[0025]
If the electrolytic voltage is not controlled by the pH sensor in step 27, the input electrolytic current value is I ′. _PiQj ± m _Three It is determined whether it is within the range (step 36). If it is within the range, return to Step 2. If it is not within the range, the input electrolytic current value is I ′ _PiQj + M _Three It is determined whether it is larger (step 37). V is larger _PiQj Subtract n (arbitrary number) from (step 38). V if not larger _PiQj Is the minimum electrolysis voltage (V _min (Step 39). V _min If not, return to Step 2. V _min V if _PiQj = V _min (Step 40). The electrolytic current value input in step 37 is I ′. _PiQj If not, jump to step 24.
[0026]
As described above, according to the alkaline ionized water device 3 having the control method of the present embodiment, when the range of flow rate that can be generated is divided into arbitrary numbers, each set pH set by the set pH input operation means. The input pH value that is detected and input by the pH sensor of the ionic water generated by electrolyzing the reference raw water at all flow rate levels each Measure the electrolysis current value and electrolysis voltage value when entering the predetermined range of the set pH value, and store the electrolysis current value and electrolysis voltage value for each flow rate level at each set pH value in the storage means. Every , When generating ionic water of the set pH value set by the set pH input operation means, it was set by the set pH input operation means. Apply the electrolytic voltage of the electrolytic voltage value stored in the storage means at the set pH value and the flow rate level at that time to the electrolytic cell, and after a predetermined time, When the input pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means, it is detected by the pH sensor. Input pH value is Set by pH input operation means The electrolytic voltage is varied so as to be within a predetermined range of the set pH value. After the predetermined time The input pH value is Set by pH input operation means Set pH value default When the control means determines that it is abnormal because it is not within the range, the electrolytic current value input by the electrolytic current input means is Set by pH input operation means Switching to a control method for generating ionic water of the set pH value by varying the electrolysis voltage so that it is within a certain range of the electrolysis current value stored in the storage means at the set pH value and the flow rate level at that time Thus, even when the MPU determines that the input pH value is abnormal, it is possible to always generate ion water having a stable set pH value.
[0027]
Further, the control method is switched to a method in which the set pH value when the input pH value falls within a predetermined range of the set pH value and the electrolysis current value and electrolysis voltage value at the flow rate level at that time are updated and stored in the storage means. In this way, it is possible to always generate ion water having a stable set pH value.
[0028]
Furthermore, during electrolysis, the input pH value is the set pH value. default If the control means determines that it is abnormal because it is not within the range of water, and the control means determines that the input pH value is abnormal by continuously passing water again and the pH value is abnormal. The control means determines that the sensor is defective, and the warning means can promptly warn of cleaning calibration or replacement.
[0029]
【Effect of the invention】
According to the first aspect of the present invention, when the range of the flow rate that can be generated is divided into arbitrary numbers, the raw water used as a reference at all the flow rate levels for each set pH value set by the set pH input operation means. Measures the electrolysis current value and electrolysis voltage value when the input pH value detected and input by the pH sensor of electrolyzed ionic water enters the specified range of each set pH value, and the flow rate at each set pH value Store the electrolytic current value and electrolytic voltage value for each level in the storage means. Every , When generating ionic water of the set pH value set by the set pH input operation means, it was set by the set pH input operation means. Apply the electrolytic voltage of the electrolytic voltage value stored in the storage means at the set pH value and the flow rate level at that time to the electrolytic cell, and after a predetermined time, When the input pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means, it is detected by the pH sensor. Input pH value is Set by pH input operation means The electrolytic voltage is varied so as to be within a predetermined range of the set pH value. After the predetermined time The input pH value is Set by pH input operation means Set pH value default When the control means determines that it is abnormal because it is not within the range, the electrolytic current value input by the electrolytic current input means is Set by pH input operation means Switching to a control method for generating ionic water of the set pH value by varying the electrolysis voltage so that it is within a certain range of the electrolysis current value stored in the storage means at the set pH value and the flow rate level at that time Can be obtained.
[0030]
According to the second aspect of the present invention, the set pH value when the input pH value falls within the predetermined range of the set pH value and the electrolytic current value and the electrolytic voltage value at the flow rate level at that time are updated and stored in the storage means. It is possible to obtain an alkaline ionized water device that can be switched to a memorized control method.
[0031]
According to the invention of claim 3, the input pH value is the set pH value during electrolysis. default If the control means determines that it is abnormal because it is not within the range of water, and the control means determines that the input pH value is abnormal by continuously passing water again and the pH value is abnormal. It is possible to obtain an alkaline ionized water device that can be determined by the control means that there is a problem with the sensor and that can be notified by the alarm means.
[Brief description of the drawings]
FIG. 1 is a schematic structural diagram of an alkaline ionized water device according to an embodiment of the present invention.
FIG. 2 is a block diagram showing the configuration of the main control part of the alkaline ionized water device according to one embodiment of the present invention.
FIG. 3 is a matrix data diagram of an alkaline ionized water device according to an embodiment of the present invention.
FIG. 4 is a flowchart of control of the alkaline ionized water device according to one embodiment of the present invention.
FIG. 5 is a flowchart of control of the alkaline ionized water device according to one embodiment of the present invention.
FIG. 6 is a flowchart of control of the alkaline ionized water device according to one embodiment of the present invention.
[Explanation of symbols]
1 Raw water pipe
2 faucets
3 Alkaline ion water conditioner
4 water purification department
5 Flow sensor
6 Calcium supply section
7 Electrolysis tank
13 pH sensor
14 Control means (MPU)
16 Power supply
17 Memory means
19 Setting pH input operation means
20 Alarm means
21 Electrolytic voltage output means
22 Electrolytic current input means
23 Electrolysis promoter supply section

Claims (3)

Flow rate input means for inputting the flow rate detected by the flow sensor, electrolytic voltage output means for outputting the voltage applied to the electrolytic cell for electrolysis, and electrolytic current input means for inputting the electrolytic current value of the current flowing through the electrolytic cell A pH sensor that detects the pH value of raw water or ionic water generated by applying an electrolysis voltage with an electrolysis voltage output means, and inputs the pH value as an input pH value, and a flow rate input by a flow rate input means The flow rate level is determined from the flow rate level, the electrolysis voltage value of the electrolysis voltage to be output to the electrolysis voltage output means is determined with respect to the flow level, the timer, the control means for calculating and inputting / outputting data, and the ions to be generated a setting pH input operation unit for inputting a switch or the like pH value of water as set pH value, when the range of the product is flow rate and level divided into any number, setting pH inputting operation means When the input pH value detected and input by the pH sensor of the ionic water generated by electrolyzing the reference raw water at all flow levels for each set pH value falls within the predetermined range of each set pH value An alkaline ionized water device comprising a storage means for measuring an electrolytic current value and an electrolytic voltage value and storing an electrolytic current value and an electrolytic voltage value for each flow level at each set pH value,
When generating ionized water having a set pH value set by the set pH input operation means, the set pH value set by the set pH input operation means and the electrolytic voltage of the electrolysis voltage value stored in the storage means at the flow rate level at that time are set. Applied to the electrolytic cell,
When the input pH value detected by the pH sensor is within the predetermined range of the set pH value set by the set pH input operation means after the predetermined time has elapsed, the input pH value detected by the pH sensor is set to the set pH input operation. Perform a control method to vary the electrolysis voltage so that it is within a predetermined range of the set pH value set by means,
If the control means determines that the input pH value detected by the pH sensor after the lapse of the predetermined time is not within the predetermined range of the set pH value set by the set pH input operation means , the electrolytic current input The electrolytic voltage is varied so that the electrolytic current value input by the means falls within a certain range of the set pH value set by the set pH input operation means and the electrolytic current value stored in the storage means at the flow rate level at that time. alkaline ionized water apparatus, characterized in that to perform another control method rather Tei. The storage means updates and stores the set pH value when the input pH value falls within a predetermined range of the set pH value, and the electrolytic current value and the electrolytic voltage value at the flow rate level at that time. The alkaline ionized water apparatus according to claim 1. During electrolysis, the control means determines that the input pH value is abnormal because the input pH value is not within the predetermined range of the set pH value and the control means determines that the input pH value is abnormal. 3. The alkaline ionized water device according to claim 1, wherein when the error occurs continuously a predetermined number of times, the control means determines that the pH sensor is defective, and notifies the alarm means.

Images