JP2001000972A - Alkali ion water maker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make ion water always having a stable set pH value until an inputted pH value is judged to be normal even if the inputted pH value from a pH sensor is judged to be abnormal and to rapidly give warning when the pH sensor is judged to be out of order so as to wash and calibrate or replace the pH sensor. SOLUTION: An alkali ion water maker is constituted of a flow rate sensor 5, an electrolytic voltage output means 21, an electrolytic voltage input means 22, a pH sensor 13, a control means 14 judging the level of a flow rate from the flow rate of the flow rate input means to perform the input and output of data, a set pH input operation means 19 and a warning means 20 making trouble known by an LED or a buzzer. When the control means judges that the inputted pH value from the pH sensor 13 is normal, it controls the electrolytic voltage due to the pH sensor and stores the electrolytic current and electrolytic voltage at this time. When the control means 14 judges the inputted pH value to be abnormal, it performs the control of the electrolytic voltage due to the electrolytic current stored when the inputted pH value is normal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention electrolyzes raw water such as tap water to produce alkaline ionized water used for drinking and medical use, and acidic ionized water used as lotion and sterilizing water. It relates to an alkali ion water purifier.

[0002]

2. Description of the Related Art In recent years, an alkali ion water conditioner has become widespread as a continuous electrolysis type ion water generator. This alkali ion water regulator electrolyzes tap water or the like in an electrolytic cell to generate acidic ion water on the anode side and generate alkali ion water on the cathode side.

A control method of a conventional continuous electrolysis type alkali ion water conditioner will be described below. Flow rate input means for inputting the flow rate of the product with a flow rate sensor, electrolytic voltage output means for outputting a voltage (hereinafter, referred to as electrolytic voltage) applied to the electrolytic cell for electrolyzing raw water, and current flowing through the electrolytic cell (hereinafter, referred to as PH for detecting the pH value of alkaline ionic water or acidic ionic water (hereinafter, ionic water) generated by applying an electrolytic voltage with electrolytic current input means for inputting an electrolytic current), raw water, or electrolytic voltage output means. The flow rate of the flow rate of the sensor and the flow rate input means is divided into q (q is an arbitrary number) ranges of flow rates that can be generated (hereinafter, flow rate level).
The control means (hereinafter referred to as MP) which determines an electrolysis voltage to be output to the electrolysis voltage output means, performs a timer, calculates data, inputs / outputs data, and the like.
U), a setting p for inputting the pH value to be generated with a switch or the like
In the configuration of H input operation means, storage means for storing data such as electrolysis current and electrolysis voltage, and alarm means for notifying a defect by an LED or a buzzer, etc., water is supplied to the product, and the flow rate inputted by the flow rate input means is stored in the storage means. Above any flow rate (below,
When the electrolytic voltage stored in the storage means corresponding to the pH value set by the set pH input operation means (hereinafter, set pH value) and the flow rate level of water flow is applied, the pH input from the pH sensor is applied. Value (hereinafter, input pH value) and set pH
A control method of varying the electrolysis voltage so that the values match is adopted.

[0004]

As described above, in the prior art, bubbles generated in water passages or the like during electrolysis rarely adhere to the pH sensor, and the pH sensor detects an erroneous pH value, For example, when a failure occurs in the pH sensor due to the cause, there is a problem that ion water having a pH value different from the set pH value is generated and provided.

Accordingly, the present invention provides an input p from a pH sensor.
Even if it is determined that the H value is abnormal, if it is determined that ion water having a stable set pH value can always be generated until the input pH value is determined to be normal, and it is determined that there is a defect in the pH sensor, It is an object of the present invention to provide an alkali ion water conditioner that can promptly warn the user to wash and calibrate or replace the pH sensor.

[0006]

In order to solve the above problems, the present invention provides a flow rate input means for inputting a flow rate such as a flow rate sensor, and an electrolytic voltage for outputting a voltage applied to an electrolytic cell for electrolysis. Output means, electrolytic current input means for inputting current flowing through the electrolytic cell, raw water, or a pH sensor for detecting the pH value of ionic water generated by applying an electrolytic voltage with the electrolytic voltage output means, and a flow rate of the flow rate input means From the flow rate level, the electrolysis voltage to be output to the electrolysis voltage output means for the flow rate level, a timer, a control means for calculating and inputting / outputting data, and a switch for the pH value to be generated. Set pH input operation means to input by, etc., storage means to store necessary data, electrolysis accelerator supply unit added to promote electrolysis such as saline solution, LED and buzzer And a warning means for informing at, when the range of the product is flow rate and level divided into any number,
At all the flow levels for each set pH, the electrolysis current and electrolysis voltage when the input pH value of the ionic water generated by electrolysis of the reference raw water matches the set pH value are measured, and the flow rate at each set pH value is measured. The matrix value of the electrolysis current and electrolysis voltage for each level is stored in the storage means, and the pH value is set and the water is passed through the product. From the start of electrolysis to the stop of electrolysis, the pH value input from the pH sensor is normal. Is applied to the electrolytic cell while varying the electrolytic voltage to bring the pH value input from the pH sensor closer to the set pH value, when the pH value input from the pH sensor matches the set pH value. The corresponding location is updated and stored in the storage means as the electrolytic current value and electrolytic voltage value of the flow rate level at the set pH value as the electrolytic current and electrolytic voltage matrix data. If the control means determines that the pH value input from the pH sensor during the electrolysis is abnormal, the input electrolysis current value is stored in advance in the matrix data or the matrix data updated in the normal state. The ionic water having a set pH value was generated by changing the electrolysis voltage so as to obtain a current value.

With this configuration, the input p from the pH sensor
Even if it is determined that the H value is abnormal, if it is determined that ion water having a stable set pH value can always be generated until the input pH value is determined to be normal, and it is determined that there is a defect in the pH sensor, It is possible to provide an alkali ion water conditioner that can promptly warn of cleaning and calibration or replacement of the pH sensor.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 is characterized in that a flow rate input means for inputting a flow rate of a flow sensor or the like, an electrolytic voltage output means for outputting a voltage applied to an electrolytic cell for electrolysis, and an electrolytic cell. Electrolytic current input means for inputting a flowing current,
A pH sensor that detects the pH value of raw water or ionic water generated by applying an electrolytic voltage with an electrolytic voltage output means, determines the flow rate level from the flow rate of the flow rate input means, and determines the electrolytic voltage with respect to the flow rate level. Judgment of the electrolytic voltage to be output to the output means, a timer, control means for calculating data, inputting / outputting data, etc., pH of ion water to be generated
Set pH input operation means for inputting a value with a switch, etc., storage means for storing necessary data, an electrolysis promoter supply unit added to promote electrolysis such as saline, etc.
And alarm means for notifying with a buzzer or the like.
At all flow levels for H, the input pH value of the ionic water generated by electrolysis of the reference raw water is set to the set pH.
The electrolysis current and electrolysis voltage at the time of coincidence with the values are measured, and stored in the storage means as matrix data of electrolysis current and electrolysis voltage for each flow rate level at each set pH value.
If the control means determines that the pH value input from the pH sensor is normal from the start of electrolysis to the stop of electrolysis after setting the H value and passing water through the product, the pH value input from the pH sensor is set to the set pH value. Is applied to the electrolytic cell while varying the electrolysis voltage in order to approach, and the pH value input from the pH sensor is set.
The electrolysis current value and the electrolysis voltage value when the H value matches are stored as matrix data of the electrolysis current and the electrolysis voltage at the flow rate level at the set pH value, and the relevant portions are updated and stored in the storage means. If the control means determines that the pH value inputted from the sensor is abnormal, the inputted electrolytic current value is set to the corresponding electrolytic current value of the matrix data stored in advance or the matrix data updated in a normal state. PH by changing the electrolysis voltage
It is designed to generate a value of ionized water.

In this configuration, when the range of the flow rate that can be generated is divided into an arbitrary number, the input pH value of the ionic water generated by electrolyzing the reference raw water at all the flow levels for each set pH The electrolytic current and the electrolytic voltage at the time when the pH value matches the set pH value are measured, and stored in the storage means as matrix data of the electrolytic current and the electrolytic voltage for each flow rate level at each set pH value.
When the MPU determines that the H value is normal, it is applied to the electrolytic cell while varying the electrolysis voltage in order to bring the input pH value closer to the set pH value, and the electrolysis current value when the input pH value matches the set pH value, The corresponding portion is updated and stored in the storage means as matrix data of the electrolytic current and the electrolytic voltage at the flow rate level at the set pH value. Input pH
If the MPU determines that the value is abnormal, the electrolysis voltage is varied so that the input electrolysis current value becomes the electrolysis current value at the flow rate level at the corresponding set pH value stored, and the setting p is set.
By switching to a control method that generates ion water having the same pH value as the H value, it is possible to always generate ion water having a stable and set pH value even when the MPU determines that the input pH value is abnormal. Become.

According to a second aspect of the present invention, after the control means determines that the pH value input from the pH sensor during electrolysis is abnormal, the control means determines that the pH value input from the pH sensor is normal again. If it is determined that the pH value input from the pH sensor is close to the set pH value, the electrolytic voltage is applied to the electrolytic cell while varying the electrolytic voltage, and the electrolytic current value when the pH value input from the pH sensor matches the set pH value By switching the electrolytic voltage value to a control method of updating the corresponding portion and storing it in the storage means as matrix data of the electrolytic current and the electrolytic voltage at the flow rate level at the set pH value,
It is possible to always generate ion water having a stable and set pH value.

According to a third aspect of the present invention, in the electrolysis, the water is stopped when the control means determines that the pH value inputted from the pH sensor is abnormal, the water is passed again, and the pH value inputted from the pH sensor is returned. If a predetermined number of consecutive occurrences of the control means determine that the is abnormal, the control means determines that there is a malfunction in the pH sensor, by notifying by the alarm means,
It is possible to promptly request cleaning and calibration or replacement of the pH sensor.

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic structural view of an alkali ion water purifier according to an embodiment of the present invention, FIG. 2 is a block diagram showing a configuration of a main control part of the alkali ion water purifier, and FIG. FIG. 4, FIG. 5, and FIG. 6 are flowcharts of the control of the alkali ion water conditioner.

FIGS. 4 to 6 show a settable pH value (P₀From
P_pFlow rate level (Q ₀To Q_q) To all
Generated by electrolysis of reference water
When the pH value of the ionized water matches the set pH value.
Solution current I_PiQjAnd electrolysis voltage V_PiQj(0 ≦ i ≦ p, 0 ≦ j ≦
q) is measured and the set pH value (P₀To P_pUp to)
Flow level (Q₀To Q_q) Of electrolysis current and electrolysis voltage
All data in the storage means
If the MPU determines that the input pH value is normal during
Changes the electrolysis voltage to bring the input pH value closer to the set pH value.
Apply to the electrolytic cell while changing it, and the input pH value will be the set pH value
Set the electrolysis current value and electrolysis voltage value when they match
Flow rate electrolysis current and electrolysis voltage mat at pH value
Update the relevant location as ricks data and store it in storage
If the MPU determines that the input pH value is abnormal,
If the input pH value is stored, the corresponding set pH value is stored.
Electrolysis voltage so that the electrolytic current value of the flow level at
A control method for generating ionized water having a set pH value,
If the pH value input from the pH sensor during electrolysis is abnormal
After judgment by the control means, input again from the pH sensor
If the control means determines that the pH value is normal,
To bring the pH value input from the sensor closer to the set pH value.
Applying to the electrolytic cell while changing the solution voltage, and from the pH sensor
Electrolytic current when the input pH value matches the set pH value
Flow rate level at the set pH value
Applicable as matrix data of electrolysis current and electrolysis voltage
A control method that updates the location and stores it in the storage means.
PH value input from pH sensor during electrolysis is abnormal
Water is stopped when the control means determines that
The control means determines that the pH value input from the sensor is abnormal.
If the disconnection occurs any number of times in a row,
The control means determines that the sensor is faulty and alerts
3 is a flowchart of a control method for causing the control to be performed.

In FIG. 1, reference numeral 1 denotes a raw water pipe such as tap water;
Is a faucet, 3 is an alkali ion water purifier connected to the raw water pipe 1 via the faucet 2, 4 is an activated carbon that absorbs residual chlorine in the raw water and a hollow fiber membrane that removes general bacteria and impurities inside. A water purification section provided, 5 is a flow rate sensor as flow rate input means for instructing control of water flow to a control means described later, 6 is a calcium supply section for increasing conductivity by giving calcium ions such as calcium glycerophosphate and calcium lactate to raw water. ,
7 is an electrolyzer for electrolyzing water passed through, 8 is an electrolyzer for 2
Separating membranes forming a sushi electrolytic chamber, 9 and 10, electrode plates disposed in each of the electrolytic chambers formed by dividing the diaphragm 8 into two, 11 being an electromagnetic valve for draining washing water, 12 being an electrode plate A discharge pipe for discharging the water on the 9 side, 13 is a pH sensor for detecting the pH of raw water or generated ionic water, 14 is a control means such as an MPU for controlling the operation of the alkali ion water purifier, and 15 is a power supply. 16 is a power supply unit for converting an alternating current from the power supply plug 15 into a direct current, 17 is a storage means for storing information on the operation of the alkali ion water dispenser, and 18 is draining water from the electrode plate 10 side. Drain pipe, 19 is a set pH input operating means for setting the pH to be generated by the alkali ion water conditioner 3, 20 is an alarm means for notifying an abnormality of the alkali ion water conditioner, and 21 is an electrolytic voltage applied to the electrolytic cell 7. Voltage output hand to perform , 22 a result of applying the electrolytic bath 7 and electrolysis voltage by electrolysis voltage output unit 21, electrolytic current input means for control instruction electrolytic current flowing through the electrolytic bath 7 to the control means 14, 23 are electrolytic accelerator supply.

Next, the operation of the above-structured alkaline ionizer for generating ionized water will be described. The user selects the pH of the alkaline ionized water or the acidic ionized water to be generated by the set pH input operation means 19. Then, the faucet 2 is opened. Raw water passed through the faucet 2 removes residual chlorine and impurities in the raw water in the water purification section 4,
The flow rate sensor 5 checks the amount of water passing, and after calcium glycerophosphate or the like is dissolved in the calcium supply unit 6 and processed into water that can be easily electrolyzed, an electrolysis accelerator such as salt water is added in the electrolysis accelerator supply unit 23 to perform electrolysis. Water is passed through 7.

On the other hand, AC 100
V is supplied, and the power supply unit 16 converts the power into a control DC power supply. When a positive voltage and a negative voltage are relatively applied to the electrode plates partitioned by the diaphragm 8 in the electrolytic cell 7, an anode chamber and a cathode chamber are formed, respectively. At this time, alkali ion water is generated on the cathode chamber side and acidic ion water is generated on the anode chamber side.

When water flows through the product, the flow sensor 5 and the control means 14 determine that water is flowing. At this time, set pH
Since the electrolysis conditions are set by the input operation means 19, the control means 14 applies an electrolysis voltage to the electrodes via the electrolysis voltage output means 21 in order to perform electrolysis by the electrolysis tank 7.
As a result, the set ion water is discharged to the water discharge pipe 12.

When the flow rate input from the flow rate sensor 5 by the alkali ion water conditioner 3 is less than an arbitrary flow rate in the storage means (hereinafter referred to as water stoppage), the polarity of the voltage is changed when a certain cleaning condition is satisfied. Invert and apply to wash the electrode plate.
Then, after the washing is completed, the electromagnetic valve 11 is opened, and the washing water is discharged from the drain pipe 18.

Next, the main part block diagram of the control method of the alkali ion water purifier 3 of the present invention shown in FIG. 2 will be described.
Reference numeral 17 denotes a ROM for storing initial values (constants) of programs and data, a RAM for storing data (variable numbers) required for operation, an EEPROM for storing data held even when the power is turned off, and the like. Storage means, 5 means a flow rate input means capable of detecting a flow rate of a flow rate sensor or the like, 21 a FET which outputs a voltage to be applied to an electrolytic cell for electrolysis.
An electrolytic voltage input means 22 for inputting a current flowing in the electrolytic cell; and 13, a raw water or an electrolytic voltage output means for detecting a pH value of ionic water generated as a result of applying an electrolytic voltage by the electrolytic voltage output means. The pH sensor 14 determines the flow rate from the flow rate of the flow rate input means, the electrolysis voltage of the electrolysis voltage output means, the timer, and the MPU for calculating data, inputting / outputting data, and the like. A set pH input operating means for setting the pH, a warning means for notifying a failure of the pH sensor 13 by a display or a buzzer, etc., and an electrolyzing agent supply section for adding an electrolyzing agent such as salt water to purified water. .

In FIG. 3 to FIG. 6, when the pH value which 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), (Hereinafter, P _i (0 ≦ i ≦ p: i, p is an arbitrary number)) is set, and after applying an electrolytic voltage,
Initialization of the time until the start of changing the electrolytic voltage (hereinafter, T1), initialization of the counters X = 0, Y = 0, Z = 0, S = 0, etc. (hereinafter, initialization 1) are performed (step). 1). Water is passed through the product, and it is determined whether the flow rate is equal to or higher than a minimum flow rate level (hereinafter, Q ₀ ) that can be generated (step 2).
If it is not equal to or greater than Q ₀ , the output of the electrolytic voltage is stopped and the process is terminated. If Q ₀ or more, the flow level is Q _j (0 ≦ j ≦ q:
j and q are arbitrary numbers), the P stored in the storage means
electrolysis voltage flow level Q _j at _i (hereinafter, V _'PiQj)
Is applied to the electrolytic cell (hereinafter, initialization 2) (step 3). If the initial setting 2 has been completed, the electrolytic voltage under control (hereinafter, 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).

Next, an electrolytic current flowing through the electrolytic cell (hereinafter referred to as I
_PiQj ) (step 6). Although T ₁ has elapsed since the start of the electrolysis is determined whether (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, the process jumps to step 36.

If T _{1 has} elapsed in step 7, the pH value of the ionic water is input by a pH sensor (step 8). It is determined whether or not the input pH value is within a range of P _i ± m ₂ (m ₂ is an arbitrary number) (step 10). If not, the process jumps to step 27. P within range
It is determined whether or not the H value is within a range of P _i ± m ₁ (m ₁ is an arbitrary number) (step 11). If not, the process jumps to step 19. If it is within the range, the counter Z =
It 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 electrolysis voltage is controlled by the pH sensor, the counter S is increased by one (step 1).
3). Then, the electrolytic voltage control by the pH sensor becomes n ₂ (n ₂
Is determined to be an arbitrary number) times (step 14). If not, the process returns to step 2. If continuous, V _PiQj and I _PiQj under control are _replaced with V ′ _PiQj and I ′
_PiQj is updated and stored in the storage means (step 15). If the electrolytic voltage control by the pH sensor is not performed in Step 10, the counter X is incremented by one (Step 1)
6). It is determined whether X is n ₁ (n ₁ is an arbitrary number) (step 17). X returns to the n ₁ unless the step 2.
X is an electrolytic voltage controlled by pH sensor if n _1,
The counter Y is set to 0 and the process returns to Step 2 (Step 18).

The pH value input in step 11 is P _i ± m ₁
If m ₁ is not within the range, the counter S =
As 0, pH value entered determines whether greater than P _i (step 19). If V _{PiQj is} larger _than n (n
Subtract any number). (Step 20) It is determined whether or not V _PiQj is equal to or lower than a minimum electrolysis voltage (hereinafter, V _min ) (Step 21). If V _min or less, V _PiQj = V _min
(Step 22). If not less than _Vmin , the process returns to step 2. PH value entered in step 19 it is determined whether P _i is smaller than (step 23). If not, return to step 2. If smaller, n (n is an arbitrary number) is added to V _PiQj (step 24). It is determined whether or not V _PiQj is equal to or higher than a maximum electrolysis voltage (hereinafter, V _max ) (step 25). If the V _max or more V _PiQj = V _max
(Step 26).

If the pH value input in step 10 is P _i ± m ₂
(M ₂ is an arbitrary number), the counter S =
As 0, it is determined whether or not the electrolytic voltage control is performed by the pH sensor (step 27). If the electrolysis voltage is controlled by the pH sensor, the counter Y is incremented by 1 (step 2).
8). It is determined whether or not Y is n ₃ (n ₃ is an arbitrary number) (step 29). X returns to the n ₃ unless the step 2.
Y is a counter Z plus 1 if n ₃ (step 30). It is determined whether Z is n ₄ (n ₄ is an arbitrary number) (step 31). If Z is n ₄ , it is determined whether or not the error has occurred again after the cleaning and the calibration after the pH sensor cleaning and the calibration request (Step 32). After requesting cleaning calibration, pH
PH, if any, after cleaning and calibrating the sensor
If it is determined that the sensor has failed, the alarm means for requesting replacement is set (step 33).
It is determined that there is a problem due to contamination of the sensor or deviation of the asymmetric potential, etc., alarm means for requesting cleaning and calibration of the pH sensor are set, and the output of the electrolytic voltage is stopped and the process is terminated (step 34). In step 31, Z is switched to the electrolysis voltage control by n ₄ unless I _'PiQj, the flow returns to Step 2 to set X to 0 (step 35).

If the electrolysis voltage control by the pH sensor is not performed in step 27, it is determined whether or not the input electrolysis current is within the range of I ′ _PiQj ± m ₃ (step 36). If it is within the range, the process returns to step 2. If not, it is determined whether or not the input electrolytic current is larger than I ′ _PiQj + m ₃ (step 37). If it is larger, n (arbitrary number) is subtracted from V _PiQj (step 38). It is large V _PiQj minimum electrolyte voltage (hereinafter, V referred _{mi n)} to determine whether or less (step 39). If not less than _Vmin , the process returns to step 2. If V _min or less, V _PiQj = V _min is set (step 40). If the electrolytic current input in step 37 is not larger than I ′ _PiQj , the process jumps to step 24.

As described above, according to the alkali ion water conditioner 3 having the control method of the present embodiment, when the range of the flow rate that can be generated is divided into arbitrary numbers, the flow rate level for each set pH value is all In, measuring the electrolysis current and the electrolysis voltage when the input pH value of the ionic water generated by electrolysis of the reference raw water is equal to the set pH value,
When the MPU determines that the input pH value is normal during electrolysis, the input pH value is stored in the storage means as matrix data of the electrolytic current and the electrolytic voltage for each flow level at each set pH value. Is applied to the electrolytic cell while varying the electrolysis voltage to approximate the electrolysis voltage, and the electrolysis current value where the input pH value matches the set pH value, and the electrolysis voltage and the electrolysis current and electrolysis voltage for each flow rate level at the set pH value The corresponding portion is updated and stored in the storage means as matrix data. When the MPU determines that the input pH value is abnormal, the electrolysis voltage is changed so that the input electrolysis current value becomes the electrolysis current value at the flow rate level at the corresponding stored set pH value, and the ionized water having the set pH value is used. Input pH value is abnormal and MPU
, It is possible to always generate ion water having a stable and set pH value.

Also, the p input from the pH sensor during electrolysis
After the control means determines that the H value is abnormal,
When the control means determines that the pH value input from the sensor is normal, the data input from the pH sensor is applied to the electrolytic cell while changing the electrolytic voltage in order to bring the pH value closer to the set pH value, and the data is input from the pH sensor. A control method for updating an electrolytic current value and an electrolytic voltage value when the pH value coincides with the set pH value as matrix data of the electrolytic current and the electrolytic voltage at the flow rate level at the set pH value and storing the data in the storage means. By switching to, it is possible to always generate ion water having a stable and set pH value.

Further, p input from a pH sensor during electrolysis
Water stops when the control means determines that the H value is abnormal,
If the control means determines that the pH value input from the pH sensor is abnormal after passing water again, the control means determines that the pH sensor has failed if the number of occurrences has occurred continuously for an arbitrary number of times, and the alarm means promptly determines the failure. Can be warned of cleaning calibration or replacement.

[0029]

According to the first aspect of the present invention, when the range of flow rates that can be generated is divided into an arbitrary number, the reference raw water is electrolyzed and generated at all the flow rate levels for each set pH. The electrolysis current and the electrolysis voltage when the input pH value of the ionic water to be supplied matches the set pH value are measured, and stored in the storage means as matrix data of the electrolysis current and the electrolysis voltage for each flow level at each set pH value. Keep it. If the control means determines that the pH value input from the pH sensor is normal from the start of electrolysis to the stop of electrolysis, the electrolytic cell is adjusted while varying the electrolysis voltage so that the pH value input from the pH sensor approaches the set pH value. Applied to
When the pH value input from the pH sensor matches the set pH value, the corresponding location is updated as matrix data of the electrolytic current and the electrolytic voltage at the flow rate level at the set pH value and the electrolytic voltage is stored in the storage means. Remember. If the control means determines that the pH value input from the pH sensor is abnormal during electrolysis, the electrolytic voltage is adjusted so that the input electrolysis current value becomes the electrolysis current value at the flow rate level at the stored set pH value. By doing so, it is possible to obtain an alkali ion water conditioner that can be switched to a control method for generating ion water having a set pH value.

According to the second aspect of the present invention, during electrolysis, p
If the control means determines that the pH value input from the H sensor is abnormal and then the control means determines that the pH value input from the pH sensor is normal again, the pH value input from the pH sensor is set to the set pH. The voltage was applied to the electrolytic cell while varying the electrolysis voltage to approach the value, and p
The corresponding locations are updated as the electrolysis current value and the electrolysis voltage value when the H value matches the set pH value and the electrolysis voltage and the electrolysis voltage at the set pH value are stored in the storage means. An alkali ion water purifier that can be switched to the control method can be obtained.

According to the third aspect of the present invention, during electrolysis, p
Any number of times that the control means determines that the pH value input from the pH sensor is abnormal, stops the water in a state where the control means determines that the pH value input from the H sensor is abnormal, and reflows water. When the occurrence occurs continuously, the control unit determines that the pH sensor is defective, and an alkali ion water conditioner that can be notified by the alarm unit can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic structural view of an alkali ion water purifier according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a main control part of the alkali ion water purifier in one embodiment of the present invention.

FIG. 3 is a matrix data diagram of an alkali ion water purifier in one embodiment of the present invention.

FIG. 4 is a flowchart of control of an alkali ion water purifier in one embodiment of the present invention.

FIG. 5 is a flowchart of control of an alkali ion water purifier in one embodiment of the present invention.

FIG. 6 is a flowchart of control of an alkali ion water purifier in one embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 raw water pipe 2 faucet 3 alkali ion water purifier 4 water purification section 5 flow sensor 6 calcium supply section 7 electrolytic tank 13 pH sensor 14 control means (MPU) 16 power supply section 17 storage means 19 set pH input operation means 20 alarm means 21 Electrolysis voltage output means 22 Electrolysis current input means 23 Electrolysis promoter supply unit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 4D061 DA03 DB01 DB08 EA02 EB12 EB37 EB38 EB39 ED12 FA09 GA02 GA15 GA22 GB02 GB19 GB22 GB30 GC02 GC12 GC14 GC20

Claims (3)

[Claims] 1. Flow rate input means for inputting a flow rate of a flow sensor or the like, electrolytic voltage output means for outputting a voltage applied to an electrolytic cell for electrolysis, electrolytic current input means for inputting a current flowing in an electrolytic cell, raw water Or a pH sensor for detecting the pH value of the ionic water generated by applying the electrolytic voltage by the electrolytic voltage output means, and determining the flow rate level from the flow rate of the flow rate input means, and outputting the electrolytic voltage for the flow rate level. Judging the electrolytic voltage to be output to the means, a timer, a control means for calculating data and inputting / outputting data, a set pH input operation means for inputting a pH value of ion water to be generated by a switch or the like, and necessary data. A storage means for storing, an electrolysis accelerator supply unit added to promote electrolysis such as a saline solution,
It is equipped with an alarm means for notifying the trouble by an LED, a buzzer, or the like, and when a range of flow rates that can be generated is divided into arbitrary numbers, at all flow rate levels for each set pH,
Measure the electrolysis current and electrolysis voltage when the input pH value of the ionic water generated by electrolyzing the reference raw water matches the set pH value, and measure the electrolysis current and electrolysis voltage for each flow rate level at each set pH value. When the control means determines that the pH value input from the pH sensor is normal from the start of electrolysis to the stop of electrolysis after setting the pH value and passing water through the product by storing it in the storage means as matrix data, The electrolytic value is applied to the electrolytic cell while varying the electrolytic voltage so that the pH value input from the pH sensor approaches the set pH value, and the electrolytic current value and the electrolytic voltage value when the pH value input from the pH sensor matches the set pH value Is updated as the matrix data of the electrolysis current and electrolysis voltage at the flow rate level at the set pH value, and the corresponding portion is updated and stored in the storage means, and the pH value input from the pH sensor during electrolysis If the control means determines that the current is abnormal, the electrolytic voltage is changed so that the input electrolytic current value becomes the corresponding electrolytic current value of the matrix data stored in advance or the matrix data updated in the normal state. An alkali ion water purifier characterized in that ion water having a set pH value is generated in the step (a). 2. When the control means determines that the pH value input from the pH sensor during electrolysis is abnormal, and when the control means determines that the pH value input from the pH sensor is normal again, the pH sensor Is applied to the electrolytic cell while varying the electrolysis voltage to bring the pH value input from
An electrolytic current value when the pH value input from the H sensor coincides with the set pH value, and an electrolytic voltage value are stored as matrix data of the electrolytic current and the electrolytic voltage at the flow rate level at the set pH value, and the relevant portions are updated and stored. The alkali ion water conditioner according to claim 1, wherein the information is stored in a memory. 3. The method according to claim 1, wherein the control means determines that the pH value input from the pH sensor during the electrolysis is abnormal, stops the water supply, re-flows water, and determines that the pH value input from the pH sensor is abnormal. 3. The alkali ion water conditioner according to claim 1 or 2, wherein when the determination of (1) occurs continuously for a predetermined number of times, the control means determines that there is a problem with the pH sensor and notifies the alarm means.