JP4369579B2 - Electrolyzed water generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an electrolyzed water generator for electrolyzing water into electrolyzed alkaline water and acidic water, and more particularly to an apparatus for displaying the pH of alkaline water or acidic water.
[0002]
[Prior art]
  Devices that electrolyze tap water and electrolyze it into alkaline water and acidic water have already been used. This apparatus can collect acidic water in the vicinity of the positive electrode and alkaline water in the vicinity of the negative electrode. For this reason, it can drain | drain from the vicinity of an electrode and can isolate | separate into alkaline water and acidic water. This type of apparatus uses alkaline water as drinking water and acidic water as water having a bactericidal effect. The pH of alkaline water and acidic water is determined by the current flowing between the electrodes and the flow rate of water passing through the ionization tank. When the flow rate is constant and the current between the electrodes increases, the pH of the alkaline water increases. Even if the current between the electrodes is kept constant and the flow rate is reduced, the pH of the alkaline water increases.
[0003]
[Problems to be solved by the invention]
  The electrolyzed water generator adjusts the pH of discharged alkaline water or acidic water by controlling the flow rate and current flowing in the ionization tank. For example, in order to discharge alkaline water having a high pH, the flow rate of water passing through the ionization tank is decreased or the current between the electrodes is increased.
[0004]
  An apparatus that can change the pH of alkaline water can be used more conveniently by displaying the pH of discharged alkaline water. This is because the user can check the pH and use it. The pH of discharged alkaline water or acidic water can be detected by a pH meter, or can be detected by calculating from the flow rate flowing through the electrolytic cell and the current value between the electrodes. The detected pH is digitally displayed as an actual numerical value.
[0005]
  This device can confirm the digital value and confirm the pH of alkaline water or acidic water. Digital values can accurately display pH. However, there is a drawback that it becomes difficult to see the numerical value when separated. There is also a drawback that it is difficult to determine the degree of pH sensuously. For example, there is a drawback that it is difficult to sensuously determine how strong alkaline water discharged exhibits alkalinity.
[0006]
  The present invention has been developed for the purpose of solving such drawbacks. An important object of the present invention is to provide an electrolyzed water generator capable of displaying the pH of alkaline water or acidic water in a state that is easy to understand sensuously.
[0007]
[Means for Solving the Problems]
  The electrolyzed water generator of the present invention has the following configuration in order to achieve the above-described object. The electrolyzed water generator includes an ionization tank 3 containing a positive electrode 1 and a negative electrode 2, a power supply 4 for applying a direct current to the positive electrode 1 and the negative electrode 2, and the pH of water discharged through the ionization tank 3. PH indicator 6 for detecting and displaying. The pH indicator 6 includes a color display panel 14 that displays pH in color. The pH indicator 6 displays the pH of the water discharged from the color display panel 14.
Furthermore, the electrolyzed water generator of the present invention includes a flow sensor 5 that detects the flow rate of water flowing into the ionization tank 3, and the power source 4 changes the current between the positive electrode 1 and the negative electrode 2 according to the flow rate. A current control circuit 4B for controlling the current control circuit 4B, and a pH indicator 6 for setting the pH of the alkaline water discharged from the ionization tank 3; In order to obtain the pH value set by the means 20, a storage means 19 is provided which stores a flow rate-current function I = f (x) as a function of the current value with respect to the flow rate. The arithmetic circuit 18 calculates the electrolytic current from the flow rate-pH function stored in the storage means 19 using the flow rate x input from the flow sensor 5 as a parameter, and the current control circuit 4B so as to obtain this electrolytic current. To control.
[0008]
  Furthermore, in the electrolyzed water generating apparatus according to claim 2 of the present invention, the pH display 6 displays a digital display panel 13 that displays the pH numerically, and a color display panel that displays the pH displayed on the digital display panel 13 in color. 14. The pH indicator 6 displays the pH of water discharged by both the digital display panel 13 and the color display panel 14.
[0009]
  Furthermore, in the electrolyzed water generating apparatus according to claim 3 of the present invention, the color display panel 14 includes a plurality of light emitting diodes 16 having different emission colors and a display plate 15 irradiated with light from the plurality of light emitting diodes 16. The color of the display plate 15 is changed by controlling the average current flowing through each light emitting diode 16.
[0010]
  Furthermore, the electrolyzed water generator according to claim 4 of the present invention allows the pulse current to flow through the plurality of light emitting diodes 16, adjusts the duty of the pulse current to flow through the light emitting diodes 16, and sets the average current flowing through the light emitting diodes 16. I have control.
[0011]
  Furthermore, in the electrolyzed water generator according to claim 5 of the present invention, the light emitting diode 16 irradiates the end face of the display plate 15.
[0012]
  Furthermore, in the electrolyzed water generator according to claim 6 of the present invention, the color display panel 14 displays the pH with letters or numbers whose luminescent colors differ depending on the pH.
Furthermore, in the apparatus for generating electrolyzed water according to claim 7 of the present invention, the storage means 19 uses I = f (x) as a flow rate-current function, ₂ x + b ₂ Is stored as a linear function.
However, in this expression, a ₂ And b ₂ Is a constant, x is a flow rate, and I is a current value.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be described below with reference to the drawings. However, the Example shown below illustrates the electrolyzed water generator for materializing the technical idea of this invention, and this invention does not specify the electrolyzed water generator to the following.
[0014]
  Further, in this specification, in order to facilitate understanding of the scope of claims, the numbers corresponding to the members shown in the embodiments are referred to as “claims” and “means for solving the problems”. It is added to the member shown by. However, the members shown in the claims are not limited to the members in the embodiments.
[0015]
  The electrolyzed water generator shown in the front view of FIG. 1 and the block diagram of FIG. 2 includes a filter 9, an ionization tank 3, a power source 4, and a pH indicator 6.
[0016]
  The filter 9 filters the supplied tap water with a filter medium to remove malodorous components such as chlorine and foreign substances contained in the water. The filter 9 has a cartridge case filled with a filtering material. The filter media has excellent adsorption capacity, such as all that can filter water clearly and remove odorous components, such as activated carbon, porous natural stone, porous natural stone pulverized and sintered into granular form, etc. Granules can be used. For example, particles having an average particle diameter of 1 to 10 mmφ are used as the filtering material.
[0017]
  The ionization tank 3 electrolyzes the water that has passed through the filter 9 and separates it into alkaline water containing positive ions and acidic water containing negative ions. The electrolyzed water ionized in the ionization tank 3 is drained from the alkaline water drainage channel 12 and the acidic water drainage channel 11. The ionization tank 3 includes a positive electrode 1 that obtains acidic water from inflowing water and a negative electrode 2 that obtains alkaline water.
[0018]
  The positive electrode 1 and the negative electrode 2 are disposed to face each other. The positive electrode 1 set on the positive side of the electrode collects negative ions such as chlorine ions when electrolyzing water, and the negative electrode 2 collects positive ions such as calcium. The positive electrode 1 is made of a material having sufficient corrosion resistance against chlorine ions.
[0019]
  The ion concentration of alkaline water and acidic water electrolyzed in the ionization tank 3, that is, pH, is determined using the electrolytic current and flow rate between the electrodes as parameters. When the electrolytic current is kept constant and the flow rate of the ionization tank 3 is decreased, the pH of the alkaline water is increased. Conversely, when the flow rate is increased, the pH of the alkaline water is decreased. The pH of alkaline water and acidic water also changes depending on the electrolysis current in the ionization tank 3, and the electrolysis current increases in proportion to the voltage between the electrodes.
[0020]
  Between the positive electrode 1 and the negative electrode 2, a porous plate 7 which is an insulating material is disposed. The porous plate 7 prevents the alkaline water and acidic water separated in the vicinity of the positive electrode 1 and the negative electrode 2 from mixing, and prevents the positive electrode 1 and the negative electrode 2 from contacting and short-circuiting.
[0021]
  Both alkaline water and acidic water flowing out from the ionization tank 3 are discharged separately. If only one electrolyzed water is drained, the other electrolyzed water concentration gradually increases. Therefore, it is not preferable to discharge only one of alkaline water and acidic water.
[0022]
  The power source 4 incorporates a constant current circuit 4 </ b> A that allows a constant electrolytic current to flow between the positive electrode 1 and the negative electrode 2 in a state in which water is allowed to flow into the ionization tank 3. The constant current circuit 4A flows an electrolytic current set between the positive electrode 1 and the negative electrode 2. For example, the constant current circuit 4 </ b> A causes a predetermined electrolytic current of 4 to 8 A to flow through the positive electrode 1 and the negative electrode 2 in the strong electrolysis mode. When the electrolysis current that the constant current circuit 4A passes through the positive electrode 1 and the negative electrode 2 is increased, the pH of the alkaline water is increased, and conversely, the pH of the alkaline water is decreased. For example, the constant current circuit 4 </ b> A is set so that an electrolytic current of 4.5 A flows between the positive electrode 1 and the negative electrode 2. The constant current circuit 4A controls the voltage applied to the positive electrode 1 and the negative electrode 2 so that the electrolysis current does not fluctuate depending on the flow rate of water flowing into the ionization tank 3 or the pH of the water.
[0023]
  The pH indicator 6 detects and displays the pH of discharged alkaline water or acidic water. The pH indicator 6 displays the pH of both alkaline water and acidic water, or displays the pH of either alkaline water or acidic water. Furthermore, the pH indicator 6 can also switch and display the pH of alkaline water and acidic water.
[0024]
  For example, the pH indicator 6 detects and displays the pH of the discharged alkaline water with a pH meter, or detects and displays the pH from the flow rate and the electrolytic current between the electrodes. An apparatus for detecting the pH of alkaline water or acidic water with a pH meter can detect the pH using a commercially available pH meter. The pH meter 10 is connected to the alkaline water drainage channel 12 and the acidic water drainage channel 11 to detect the pH of alkaline water and acidic water, as indicated by the chain line in FIG. The detected pH is displayed on the pH display 6.
[0025]
  The device in which the pH indicator 6 calculates the pH from the flow rate and the electrolysis current includes a flow rate sensor 5 that detects the flow rate of water flowing into the ionization tank 3. The pH indicator 6 calculates a pH by calculating a signal input from the flow sensor 5 and an electrolytic current input from the power source 4. The pH indicator 6 is advantageous in that it can be manufactured at a low cost and can be easily maintained as compared with a pH meter.
[0026]
  The pH display 6 in FIG. 1 includes a digital display panel 13 that displays the pH of alkaline water and acidic water of electrolyzed water numerically, and a color display panel 14 that displays the pH displayed on the digital display panel 13 in color. . In the pH display 6 in this figure, the color display panel 14 has an outer shape larger than that of the digital display panel 13, and the digital display panel 13 is disposed inside the color display panel 14. The pH display 6 can display the surroundings of the digital display panel 13 with the color display panel 14 and display the pH in color. However, the color display panel can also be displayed with the top and bottom and left and right larger than the digital display panel. Further, the color display panel can be arranged and displayed near the digital display panel.
[0027]
  The digital display panel 13 is laminated on the upper surface of the color display panel 14 as shown in the cross-sectional views of FIGS. The color display panel 14 includes a display plate 15 that displays pH in color, a plurality of light-emitting diodes 16 that cause the surface of the display plate 15 to emit light in a specific color, and a lighting circuit 17 that lights the light-emitting diode 16 in a specific color. With.
[0028]
  The display plate 15 is a transparent plate such as glass or plastic plate that can transmit light. The display plate 15 irradiates the plurality of light emitting diodes 16 so that the entire surface uniformly emits light in a specific color. In other words, the display plate 15 mixes the light emission colors of the plurality of light emitting diodes 16 to make the entire surface uniform. Therefore, the display plate 15 has one or both of the front surface and the back surface provided with fine uneven portions 15A to scatter light. The surface of the display plate 15 is provided with irregularities so that the entire surface can emit light with uniform brightness. The display plate can also emit light with a uniform color by mixing white powder that scatters light inside without providing irregularities on the surface. Moreover, it can also be set as the structure which mixes white powder and provides an unevenness | corrugation on the surface.
[0029]
  The plurality of light emitting diodes 16 that irradiate the display plate 15 are arranged close to the display plate 15. The color display panel 14 shown in FIG. 3 has a plurality of light emitting diodes 16 disposed on the back surface of the display plate 15. The color display panel 14 having this structure has a feature that light can be irradiated toward the surface of the panel. The color display panel 14 shown in FIGS. 4 and 5 has a plurality of light emitting diodes 16 disposed on the end face of the display plate 15. The color display panel 14 can emit light on the entire surface of the display plate 15 by reflecting or totally reflecting the irradiated light on the reflection surface with the bottom and side surfaces of the display plate 15 as reflection surfaces. The color display panel 14 having this structure has a feature that it can be disposed in a space-saving manner by making the whole thin.
[0030]
  Further, the light emitting diode 16 that irradiates the display plate 15 is provided with a plurality of light emitting diodes having different emission colors arranged close to each other. As the light emitting diodes 16 having different emission colors, a combination of a red light emitting diode, a green light emitting diode, and a blue light emitting diode is optimal. The light emitting diode 16 can be displayed in full color with the three light emitting diodes 16. However, the light emitting diode may be a combination of a red light emitting diode and a blue light emitting diode. This is because the color display panel 14 that displays pH in color can display pH in red, blue, and an intermediate color thereof. The light emitting diode 16 is a unit in which a red light emitting diode, a green light emitting diode, and a blue light emitting diode are arranged close to each other, or from a red light emitting diode, a green light emitting diode, and a blue light emitting diode. These three light emitting diodes can be arranged close to each other.
[0031]
  The display plate 15 is irradiated with at least two light emitting diodes 16 including a red light emitting diode and a blue light emitting diode. When the number of the light emitting diodes 16 is increased, the display plate 15 can emit light brightly. The number of the light emitting diodes 16 is set to an optimum value in consideration of the size of the transparent plate 15, the required brightness, and the light emission intensity of the light emitting diodes 16. For example, the display plate 15 having an area of 10 to 100 cm 2 is irradiated with 10 to 100 light emitting diodes 16. A display plate using red light emitting diodes, green light emitting diodes, and blue light emitting diodes having the same light emission intensity uses the same number of light emitting diodes 16 of each color. However, a color display panel that uses different light emitting intensities for each light emitting diode uses a larger number of dark light emitting diodes than bright light emitting diodes.
[0032]
  The light emitting diodes 16 of the respective light emission colors adjust the light emission intensity by controlling the current, and the light emission color of the display plate 15 is adjusted by the light emission intensity of each light emitting diode 16. When the red light emitting diode emits light strongly, the surface of the display plate 15 approaches red, and when the blue light emitting diode emits light strongly, the surface of the display plate 15 approaches blue.
[0033]
  The current of each light emitting diode 16 can be controlled by controlling the average current value. Further, the average current flowing through the light emitting diode 16 may be controlled by adjusting the duty of the pulse current, which is the ratio of the time during which the pulse current is passed through the light emitting diode 16 and the time during which the current is cut off. it can. The lighting circuit 17 that adjusts the average current of the light emitting diodes 16 with the duty can control the light emission intensity of each light emitting diode 16 by turning on and off switching elements such as transistors and FETs. For this reason, the lighting circuit 17 can be simplified and the power loss of the lighting circuit 17 can be reduced. This is because the power loss due to the voltage drop of the switching element that is turned on and off can be reduced.
[0034]
  The lighting circuit 17 that adjusts the average current of the light emitting diode 16 with the duty of the pulse current controls the pulse current of the light emitting diode 16 to be constant. For example, the pulse current of the light emitting diode 16 is driven at a constant current of 10 to 50 mA. The period of the pulse current, in other words, the frequency of the pulse current is set to 50 Hz to 1 MHz so that the blinking flicker is not recognized. When the period of the pulse current is slowed, flickering is conspicuous. On the contrary, if the cycle of the pulse current is shortened, the flicker becomes inconspicuous, but it is necessary to turn on and off the switching element at high speed, and it is necessary to use a high-speed element for the switching element and the drive circuit of the switching element.
[0035]
  The lighting circuit 17 for adjusting the average current of the light emitting diode 16 by controlling the duty of the pulse current increases the average current of the light emitting diode 16 by increasing the time for supplying the pulse current or shortening the time for interrupting the current. To brighten the light. The lighting circuit 17 controls the light emission intensity of the light emitting diodes 16 by controlling the duty of each light emitting diode 16 so that the surface of the display plate 15 has a color corresponding to pH. When the lighting circuit 17 increases the average current of the red light emitting diode, the surface of the display plate 15 becomes red, and when the average current of the blue light emitting diode is increased, the surface of the display plate 15 becomes blue.
[0036]
  The color display panel 14 described above uses a plurality of light emitting diodes 16 having different emission colors to cause the display plate 15 to emit light. However, as the light emitting diode for irradiating the display plate, as shown in FIGS. 6 and 7, a single light emitting diode capable of full color display can be used. The light-emitting diode 16 includes a red light-emitting chip, a green light-emitting chip, and a blue light-emitting chip, and adjusts the light emission intensity of each light-emitting chip by controlling the current flowing to the terminal connected to each light-emitting chip, The emission color of the light emitting diode 16 is adjusted.
[0037]
  The light emitting diode 16 can control the light emission intensity by controlling the average current value flowing through each terminal. As described above, the light emitting diode 16 adjusts the duty of the pulse current, which is the ratio of the time for supplying the pulse current and the time for interrupting the current, by the lighting circuit 17 to control the average current supplied to each terminal. it can. The lighting circuit 17 controls the duty of each terminal and the light emission intensity of the light emitting diode 16 so that the surface of the display plate 15 has a color corresponding to pH. As described above, a color display panel using a single light emitting diode capable of full color display has a feature that it can be designed compactly, can be disposed in a small space, and can emit light efficiently.
[0038]
  The lighting circuit 17 is controlled by the arithmetic circuit 18. The arithmetic circuit 18 controls the lighting circuit 17 so that the display plate 15 emits light in a color corresponding to the pH of alkaline water or acidic water. As indicated by a chain line in FIG. 2, the pH indicator 6 that detects the pH by using the pH meter 10 controls the lighting circuit 17 by the arithmetic circuit 18 based on the pH value signal input from the pH meter 10. The display plate 15 is caused to emit light. As shown in FIG. 2, in the pH indicator 6 in which the arithmetic circuit 18 calculates the pH, the arithmetic circuit 18 controls the lighting circuit 17 so that the display plate 15 emits light in a color corresponding to the calculated result. Further, the arithmetic circuit 18 controls the digital display panel 13 to digitally display the calculated pH as a numerical value.
[0039]
  The above pH indicator 6 digitally displays the pH value of alkaline water or acidic water on the digital display panel 13 and displays the color corresponding to this pH value on the color display panel 14. However, the electrolyzed water generator of the present invention can display the pH of alkaline water and acidic water only with a color display panel without using a digital display panel as a pH indicator. In this pH indicator, the color display panel displays the pH value of alkaline water and acidic water with letters and numbers having different emission colors. A color display panel having this structure is shown in FIGS.
[0040]
  A color display panel 14 shown in FIG. 14 includes a liquid crystal character display board 21 that displays characters and numbers in color, and a control circuit 22 that controls the liquid crystal character display board 21. The liquid crystal character display board 22 has a built-in light source, transmits light of a specific wavelength from the light emitted from the light source, and displays characters and numbers on the surface in color. The control circuit 22 controls characters and numbers displayed on the liquid crystal character display board 21 and colors for displaying them based on an input signal from an arithmetic circuit (not shown). The color display panel 14 controls the liquid crystal character display board 21 with a control circuit 22 to digitally display the pH value of alkaline water or acidic water, and adjust the color of displayed characters and numbers to a predetermined color. Are displayed in color.
[0041]
  A color display panel 14 shown in FIG. 15 includes a plurality of light emitting diodes 16 having different emission colors and a lighting circuit 17 that controls light emission of these light emitting diodes 16. The light emitting diodes 16 having different emission colors are a combination of a red light emitting diode, a green light emitting diode, and a blue light emitting diode. The three light emitting diodes 16 are arranged close to one unit so that full color display can be performed. The color display panel 14 shown in the drawing arranges the light emitting diode units 23 at predetermined positions so that the pH value of alkaline water or acidic water can be digitally displayed. However, the color display panel can also display the pH value with letters and numbers using a commercially available display panel in which a light emitting diode unit is disposed on the entire surface. The lighting circuit 17 lights a light emitting diode 16 of a specific color at a specific position based on an input signal from an arithmetic circuit (not shown). This color display panel also digitally displays the pH value of alkaline water or acidic water, and displays the color by adjusting the light emitting diode unit 23 to a color corresponding to the pH value. However, the light emitting diodes can also be displayed by combining light emitting diodes of two different colors.
[0042]
  The color displayed by the color display panel 14 is changed according to the pH value of alkaline water or acidic water. The pH indicator 6 can determine the degree of pH of alkaline water or acidic water from the difference in color displayed by the color display panel 14. As shown in FIG. 8, the color displayed on the color display panel can be continuously changed with the change of the pH value. The pH indicator gradually changes the average current of the plurality of light emitting diodes according to the pH value, and gradually changes the color displayed by the color display panel. Since this pH indicator can continuously change the color to be displayed, for example, alkaline water having a pH between strong alkaline water and weak alkaline water is displayed in an intermediate color between strong alkaline water color and weak alkaline water color. Thus, there is a feature that the degree of pH can be determined by a change in the hue of the intermediate color.
[0043]
  Further, the color displayed by the color display panel can be changed step by step as shown in FIG. This pH indicator displays a color corresponding to a pH value in a preset range on a color display panel. This pH indicator has the feature that the pH of alkaline water and acidic water can be divided into a plurality of regions, and the strength of alkaline water and acidic water can be clearly displayed step by step.
[0044]
  The arithmetic circuit 18 shown in FIG. 2 calculates the pH of alkaline water from the flow rate of water flowing into the ionization tank 3 while keeping the electrolytic current constant. Therefore, the pH indicator 6 in this figure is calculated from the storage means 19 storing y = f (x), which is a flow rate-pH function, and the flow rate-pH function y = f (x) of the storage means 19. And an arithmetic circuit 18 for correcting the pH value by adding the corrected pH of the water flowing into the ionization tank 3.
[0045]
  The storage means 19 stores y = f (x), which is a flow rate-pH function, as y = a₁x + b₁Is stored as a linear function. However, in this expression, a₁And b₁Is a constant, x is a flow rate, and y is a pH value. The storage means 19 need not store a plurality of flow rate-pH functions y = f (x). The stored flow rate-pH function y = f (x) is one function. An apparatus for setting the set current of the constant current circuit 4A to 4.5 A is shown in FIG.₁And b₁The value of a₁= -1 / 11, b₁= 111.5 / 11. A in the flow rate-pH function₁And b₁Is set to an optimum value by the flow rate value of the constant current circuit 4A.
[0046]
  The arithmetic circuit 18 adds and corrects the corrected pH to the calculated pH value calculated from y = f (x), which is the flow rate-pH function stored in the storage unit 19, and displays the corrected pH value. . The corrected pH is determined by the quality of the water flowing into the ionization tank 3. The corrected pH is a value specified in the range of −0.5 to +0.5. A simple apparatus sets the correction pH to a constant value regardless of the flow rate of the ionization tank 3. However, the corrected pH can be changed by the flow rate.
[0047]
  The corrected pH is determined by discharging alkaline water at a specific flow rate when the electrolyzed water generator is first installed. The corrected pH is the difference between the pH calculated from the flow rate-pH function y = f (x) and the pH of the alkaline water that is actually discharged. For example, in the aforementioned flow rate-pH function y = f (x), when 1.5 liters of alkaline water is discharged per minute, the calculated pH value becomes 10. In this state, the pH of the alkaline water drained from the electrolyzed water generator is actually measured, and if the measured pH value is 10.2, the corrected pH is 0.2. Since the corrected pH is a constant that does not change, the arithmetic circuit 18 always adds the correction pH of 0.2 to the calculated pH value calculated from the flow rate-pH function y = f (x) to obtain the pH value. To detect.
[0048]
  However, the corrected pH can also be determined by measuring the pH of the water flowing into the ionization tank 3 when the electrolyzed water generator is first installed. In this apparatus, the correction pH is set to a difference between the pH of the inflowing water and “7” which is the pH value of the neutral water. For example, when the pH value of the inflowing water is “7.5”, the correction pH is set to +0.5. Since the corrected pH is a constant that does not change, the calculation circuit 18 always adds 0.5 as the corrected pH to the calculated pH value calculated from the flow rate-pH function y = f (x). To detect.
[0049]
  The correction pH may be a constant that changes with the flow rate. This apparatus measures the pH of the alkaline water discharged by changing the flow rate, compares the measured pH value with the calculated pH value, and determines the corrected pH at each flow rate. In this case, it is not always necessary to actually measure the pH of the alkaline water at all flow rates. The pH of the alkaline water is measured at the maximum flow rate and the minimum flow rate, and the calculated pH value is calculated from the flow rate-pH function y = f (x), and the corrected pH at the maximum flow rate and the corrected pH at the minimum flow rate are calculated from the difference. And the corrected pH at an intermediate flow rate is calculated by a linear function.
[0050]
  The flow sensor 5 measures the flow rate of water passing through the ionization tank 3. As the flow rate sensor 5, all sensors that measure the flow rate of water and output an electrical signal can be used. For example, the flow sensor 5 can be a sensor that rotates the rotor in proportion to the flow rate of water passing when the water flows, and converts the rotation of the rotor into an electrical signal and outputs it. The flow rate sensor 5 can detect the flow rate of water passing through the ionization tank 3 at the number of rotations of the rotor that rotates per minute.
[0051]
  The generator shown in FIG. 2 is provided with an on-off valve 8 on the inflow side. When the opening degree of the on-off valve 8 is adjusted, the flow rate of water flowing into the ionization tank 3 changes. When the on-off valve 8 is fully opened, the flow rate of the water passing through the ionization tank 3 increases and the pH of the alkaline water decreases, and when it is squeezed, the flow rate of the water decreases and the pH of the alkaline water increases.
[0052]
  The flow sensor 5 is also used in a safety circuit that does not apply a voltage to the electrode when water does not flow into the ionization tank 3. In this apparatus, the flow rate sensor 5 controls on / off of the power source 4. The flow sensor 5 applies a voltage to the positive electrode 1 and the negative electrode 2 only when detecting that water flows into the ionization tank 3. When it is detected that water does not flow into the ionization tank 3, the output of the power source 4 is turned off and the output voltage is set to 0V.
[0053]
  In the apparatus of this figure, when the on-off valve 8 is opened and water enters the ionization tank 3, this is detected by the flow sensor 5, and the power source 4 is connected to the positive electrode 1 and the negative electrode 2 of the ionization tank 3. In addition, an electrolytic current is passed at a constant current. In this state, the flow rate of water passing through the ionization tank 3 is detected by the flow rate sensor 5. From the flow rate detected by the flow rate sensor 5, the calculation circuit 18 calculates the pH of the alkaline water based on y = f (x) which is a flow rate-pH function stored in the storage unit 19. Further, the arithmetic circuit 18 adds the corrected pH to the calculated calculated pH value to detect the correct pH of the alkaline water.
[0054]
  The user adjusts the opening degree of the on-off valve 8 when changing the pH of the discharged alkaline water. If the flow rate is reduced by narrowing the on-off valve 8, the pH of the alkaline water discharged from the ionization tank 3 increases. The arithmetic circuit 18 calculates the calculated pH value from the reduced flow rate, corrects the calculated pH value, and detects it as the pH of the alkaline water. The electrolyzed water generator described above adjusts the opening degree of the on-off valve 8 to change the pH of the discharged alkaline water.
[0055]
  FIG. 11 shows an electrolyzed water generator capable of discharging alkaline water having a set pH. This device controls the pH of discharged alkaline water to be constant even if the flow rate of water passing through the ionization tank 3 changes.
[0056]
  The electrolyzed water generator shown in this figure includes a filter 9, an ionization tank 3, a power supply 4, and a pH indicator 6 as in the apparatus shown in FIG. 2. The filter 9, the ionization tank 3, and the on-off valve 8 are the same as the apparatus of FIG.
[0057]
  The power supply 4 has a built-in current control circuit 4 </ b> B that changes the current according to the flow rate between the positive electrode 1 and the negative electrode 2 in a state where water flows into the ionization tank 3. The current control circuit 4B is controlled by the arithmetic circuit 18 to change the electrolysis current so that the pH of the discharged alkaline water becomes constant. For example, the current control circuit 4B allows the electrolytic current controlled to 2 to 3 A to flow in the strong drinking mode in which the pH of the alkaline water is set to 9.5. In the weak drinking mode in which the pH of the alkaline water is set to 9.0, an electrolytic current controlled to 1 to 1.2 A is passed.
[0058]
  The current control circuit 4 </ b> B changes the electrolysis current passed through the positive electrode 1 and the negative electrode 2 according to the flow rate of water in the ionization tank 3. This is for adjusting the pH of the discharged alkaline water to be the same. The current control circuit 4B controls the electrolysis current to be large when the flow rate of water in the ionization tank 3 is large, and conversely controls the electrolysis current to be small when the flow rate is small. Preferably, the current control circuit 4B sets the electrolysis current to 3A when the flow rate of water in the ionization tank 3 is set to 6 liters / minute, and sets the electrolysis current to 2A when the flow rate is set to 1.5 liters / minute. .
[0059]
  The pH indicator 6 has a setting means 20 for setting the pH of the alkaline water discharged from the ionization tank 3, and a flow rate-current as a function of the current value with respect to the flow rate in order to obtain the pH value set by the setting means 20. Storage means 19 for storing the function I = f (x).
[0060]
  The setting means 20 includes a switch that controls the strong drinking mode and the weak drinking mode. In the strong drinking mode, the pH of the alkaline water is set to 9.5, and in the weak drinking mode, the pH of the alkaline water is set to 9.0. The set pH of the alkaline water is digitally displayed on the digital display panel 13. Further, the color display panel 14 is displayed in a color corresponding to the set pH.
[0061]
  The storage means 19 stores I = f (x), which is a flow rate-current function, as I = a₂x + b₂Is stored as a linear function. However, in this expression, a₂And b₂Is a constant, x is a flow rate, and I is a current value. The storage means 19 stores a flow rate-current function I = f (x) corresponding to the strong drinking mode and the weak drinking mode. A flow rate-current function corresponding to the strong drinking mode is shown in FIG. 12, and a flow rate-current function I = f (x) corresponding to the weak drinking mode is shown in FIG.
[0062]
  Flow rate-current function I = a in the strong drinking mode shown in FIG.₂x + b₂Is a₂Is 1 / 4.5, b₂Is 7.5 / 4.5. Flow rate-current function I = a in the weak drinking mode shown in FIG.₂x + b₂Is a₂Is 0.2 / 4.5, b₂Is 4.2 / 4.5.
[0063]
  The arithmetic circuit 18 uses the flow rate x input from the flow rate sensor 5 as a parameter, and is stored in the storage unit 19. The flow rate-pH function I = a₂x + b₂Then, the electrolysis current is calculated, and the current control circuit 4B is controlled so as to be the electrolysis current. The arithmetic circuit 18 determines the flow rate-pH function I = a depending on the drinking mode.₂x + b₂And the electrolysis current is calculated with the selected flow rate-current function. Therefore, when the setting means 20 is set to the strong drinking mode, the electrolytic current is calculated from the flow rate-current function I = f (x) shown in FIG. 12, and when the weak drinking mode is set, the flow rate shown in FIG. Calculate the electrolysis current from the current function I = f (x).
[0064]
  The generator shown in FIG. 11 does not change the pH of discharged alkaline water even when the flow rate of water flowing into the ionization tank 3 is changed by the on-off valve 8 provided on the inflow side. That is, when the flow rate of water in the ionization tank 3 is changed, the flow rate is detected by the flow rate sensor 5, the electrolytic current is calculated from the detected flow rate, and the current control circuit 4 B is the positive electrode 1 so that the calculated electrolytic current is obtained. This is because the electrolytic current between the negative electrode 2 and the negative electrode 2 is controlled.
[0065]
  For example, when the flow rate of the water passing through the ionization tank 3 changes in the state where the setting means 20 is set to the strong drinking mode, the arithmetic circuit 18 causes the flow rate-current function I = f of FIG. The electrolytic current is calculated from (x). The current control circuit 4B controls the voltage between the positive electrode 1 and the negative electrode 2 so that the calculated electrolysis current is obtained. For this reason, even if the flow rate of the ionization tank 3 changes, the pH of the discharged alkaline water is kept constant. When the setting means 20 is set to the weak drinking mode, the arithmetic circuit 18 calculates the electrolytic current based on the flow rate-current function I = f (x) shown in FIG. 13, and current control is performed so as to be the electrolytic current. Since the electrolytic current of the ionization tank 3 is controlled by the circuit 4B, the pH of the discharged alkaline water becomes the pH set in the weak drinking mode.
[0066]
【The invention's effect】
  The electrolyzed water generator of the present invention has an advantage that the pH of alkaline water or acidic water can be displayed in a state that can be easily understood. That is, the electrolyzed water generator of the present invention includes a color display panel for color-displaying pH on a pH indicator that detects and displays the pH of water discharged through the ionization tank. This is because the pH of the discharged water is displayed. The electrolyzed water generator having this structure displays the pH of alkaline water or acidic water in a color display panel, so that it can be displayed in a state that is easy to understand. For this reason, the electrolyzed water generating device of the present invention, unlike the conventional device, does not read the pH value with digital numbers, in other words, it judges the degree of pH by color even from a distant position, and The pH of alkaline water or acidic water can be recognized safely and safely without misreading like numbers. Furthermore, since the electrolyzed water generator of the present invention displays the pH of alkaline water and acidic water in color, even a general user without chemical expertise can experience sensual and experience with color differences. Therefore, it can be easily determined how strong the alkaline water or acidic water discharged is. Therefore, without limiting the age and knowledge of the user, it is possible to realize a feature that many people of a wide range of ages, from children to the elderly, can use with confidence in the correct usage method.
[0067]
  Further, the electrolyzed water generator according to claim 2 of the present invention has the feature that it can display the pH value accurately in addition to being able to display the pH of alkaline water or acidic water in a state that is intuitively understandable. That is, the electrolyzed water generator of the present invention includes a digital display panel for displaying pH numerically and a color display panel for displaying pH in color on a pH indicator, both in the digital display panel and the color display panel. This is because the pH of the discharged water is displayed. This device has the feature that it can be used with confidence by recognizing the pH sensuously with the color displayed on the color display panel, and more accurately checking the pH value with the number displayed on the digital display panel. is there.
[0068]
  Furthermore, the electrolyzed water generator according to claim 5 of the present invention is characterized in that the light emitting diode irradiates the end face of the display plate, so that the entire color display panel can be made thin and disposed in a space-saving manner.
[0069]
  Furthermore, in the electrolyzed water generator according to claim 6 of the present invention, since the color display panel displays the pH with letters or numbers whose luminescent colors differ depending on the pH, the pH of alkaline water or acidic water can be accurately adjusted. It has the feature that it can be displayed in a state that is intuitively understandable.
[Brief description of the drawings]
FIG. 1 is a front view of an electrolyzed water generator according to an embodiment of the present invention.
FIG. 2 is a block diagram of an electrolyzed water generator according to an embodiment of the present invention.
FIG. 3 is a sectional view of a color display panel of a pH indicator.
FIG. 4 is a sectional view showing another example of the color display panel of the pH indicator.
5 is a plan view of the color display panel shown in FIG.
FIG. 6 is a cross-sectional view illustrating another example of a color display panel.
FIG. 7 is a cross-sectional view showing another example of a color display panel.
FIG. 8 is a graph showing a change in hue displayed on the color display panel.
FIG. 9 is a graph showing another example of a change in hue displayed on the color display panel.
FIG. 10 is a graph showing the flow rate-pH function y = f (x) stored in the storage means.
FIG. 11 is a block diagram of an electrolyzed water generator according to another embodiment of the present invention.
12 is a graph showing a flow rate-current function I = f (x) corresponding to the strong drinking mode stored in the storage unit of the electrolyzed water generator shown in FIG.
13 is a graph showing a flow rate-current function I = f (x) corresponding to the weak drinking mode stored in the storage unit of the electrolyzed water generator shown in FIG.
FIG. 14 is a plan view of a color display panel of an electrolyzed water generator according to another embodiment of the present invention.
FIG. 15 is a partially enlarged plan view of a color display panel of an electrolyzed water generator according to another embodiment of the present invention.
[Explanation of symbols]
    1 ... Positive electrode
    2 ... Negative electrode
    3 ... Ionization tank
    4 ... Power supply 4A ... Constant current circuit 4B ... Current control circuit
    5 ... Flow sensor
    6 ... pH indicator
    7. Perforated plate
    8 ... Open / close valve
    9 ... Filter
  10 ... pH meter
  11 ... Acidic water drainage channel
  12 ... Alkaline water drainage channel
  13. Digital display panel
  14 ... Color display panel
  15 ... Display plate 15A ... Uneven portion
  16 ... Light emitting diode
  17 ... Lighting circuit
  18 ... arithmetic circuit
  19. Storage means
  20: Setting means
  21 ... Liquid crystal character display board
  22 ... Control circuit
  23 ... Light emitting diode unit

Claims (7)

An ionization tank (3) containing a positive electrode (1) and a negative electrode (2), a power supply (4) for applying a direct current to the positive electrode (1) and the negative electrode (2), and an ionization tank (3) In an electrolyzed water generator comprising a pH indicator (6) for detecting and displaying the pH of discharged water, and a flow rate sensor (5) for detecting the flow rate of water flowing into the ionization tank (3) ,
The power source (4) has a current control circuit (4B) that changes a current according to a flow rate between a positive electrode (1) and a negative electrode (2), and an arithmetic circuit (18) that controls the current control circuit (4B). And
The pH indicator (6) includes a color display panel (14) for displaying pH in color, and displays the pH of water discharged from the color display panel (14) .
The pH indicator (6) has a setting means (20) for setting the pH of the alkaline water discharged from the ionization tank (3) and a pH value set by the setting means (20). Storage means (19) for storing a flow rate-current function I = f (x) as a function of the current value,
The arithmetic circuit (18) calculates the electrolytic current from the flow rate-pH function stored in the storage means (19) using the flow rate x input from the flow rate sensor (5) as a parameter, and becomes this electrolytic current. As described above, the electrolyzed water generator is configured to control the current control circuit (4B) .   The pH indicator (6) includes a digital display panel (13) for displaying the pH numerically and a color display panel (14) for displaying the pH displayed by the digital display panel (13). The apparatus for generating electrolyzed water according to claim 1, characterized in that the pH of water discharged from both (13) and the color display panel (14) is displayed.   The color display panel (14) has a plurality of light emitting diodes (16) having different emission colors and a display plate (15) irradiated with light from the plurality of light emitting diodes (16), and each light emitting diode (16) 2. The electrolyzed water generator according to claim 1, wherein the color of the display plate (15) is changed by controlling an average current flowing through the water.   The electrolytic current according to claim 3, wherein a pulse current is supplied to the plurality of light emitting diodes (16) and a duty of the pulse current supplied to the light emitting diode (16) is adjusted to control an average current supplied to the light emitting diode (16). Water generator.   4. The electrolyzed water generator according to claim 3, wherein the light emitting diode (16) irradiates the end face of the display plate (15).   The electrolyzed water generator according to claim 1, wherein the color display panel (14) displays the pH with letters or numbers whose luminescent colors differ depending on the pH. The electrolyzed water generator according to claim 1, wherein the storage means (19) stores I = f (x), which is a flow rate-current function, as a linear function of I = a ₂ x + b ₂ .
In this equation, a ₂ and b ₂ are constants, x is a flow rate, and I is a current value.

Images