JP2004081991A - Method and equipment for taking-out electrolytic alkaline water - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and equipment to selectively take out an electrolytic alkaline water of high hydrogen content or low hydrogen content. <P>SOLUTION: The electrolytic alkaline water taking-out equipment is provided with an electrolytic water producing device 2 for producing the electrolytic alkaline water containing colloidal hydrogen, a tank 3 for storing the electrolytic alkaline water supplied from the electrolytic water producing device 2 and taking-out passages 5,6 for individually taking-out the electrolytic alkaline water from each of an upper part 4a and a lower part 4b of a storing region 4 of the tank 3. Electrolytic alkaline water Ba taken out of the upper part 4a of the storing region of the tank 3 is of a high hydrogen content because of high colloidal hydrogen content. Reversely electrolytic alkaline water Bb taken out of the lower part 4b of the storing region of the tank 3 is of lower hydrogen content compared with the electrolytic alkaline water Ba because of low colloidal hydrogen content or no colloidal hydrogen content. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an extraction method and an extraction device for extracting electrolytic alkaline water from an electrolytic water generator that generates electrolytic alkaline water containing colloidal hydrogen.
[0002]
[Prior art]
Some of the hydrogen generated by electrolysis in the cathode chamber of the electrolyzed water generator is released as air bubbles, some remains in the liquid as dissolved hydrogen, and when the electrolysis current is increased, part of the hydrogen is released. It becomes a colloid and remains in a large amount in the liquid. Electrolyzed alkaline water generated in the cathode chamber contains dissolved hydrogen by dissolving hydrogen generated by electrolysis into a solution, and the dissolved hydrogen is a factor showing reducibility. Electrolytic alkaline water has a high reducing power if the total amount of hydrogen contained in the water as dissolved hydrogen and colloidal hydrogen (hereinafter, referred to as "hydrogen content") increases, so it is used in reactions requiring high reducing power. Sometimes, a higher hydrogen content is required, and conversely, when a lower reducing power is required, it is necessary to reduce the hydrogen content. When electrolytic alkaline water immediately after generation is used, the hydrogen content may include hydrogen existing as bubbles.
[0003]
[Problems to be solved by the invention]
Then, the inventors repeated many tests so as to selectively extract electrolytic alkaline water having a large or small hydrogen content, and as a result, obtained the following items, and reached the present invention. In other words, the colloidal hydrogen remaining in the liquid when the electrolytic current is increased is concentrated on the electrolytic alkaline water when stored in the tank, and is located in the form of ordinary dissolved hydrogen without colloidal by dilution. You can easily change it. Further, the colloidal hydrogen can be removed by pressurizing with a pump.
[0004]
An object of the present invention is to provide a method and an apparatus for extracting electrolytic alkaline water that can selectively extract electrolytic alkaline water having a high or low hydrogen content.
[0005]
[Means for Solving the Problems]
Means adopted by the present invention according to claim 1 in order to be able to selectively remove electrolytic alkaline water having a large or small amount of hydrogen is an electrolytic solution containing colloidal hydrogen generated by an electrolytic water generating apparatus. Alkaline water is stored in a tank.Electrolytic alkaline water with a high content of colloidal hydrogen is located in the upper part of the storage area, and whether the content of colloidal hydrogen in the lower part is smaller than that in the upper part. Alternatively, there is provided a method for removing electrolytic alkaline water, wherein the electrolytic alkaline water having no electrolyte is located and upper and / or lower electrolytic alkaline water is individually removed.
[0006]
According to the first aspect of the present invention, electrolytic alkaline water having a high content of colloidal hydrogen is obtained by extracting electrolytic alkaline water from the upper part of the storage area of the tank, and electrolytic alkaline water is obtained from the lower part of the storage area of the tank. By taking out water, electrolytic alkaline water having little or no colloidal hydrogen content can be obtained. Electrolyzed alkaline water taken out from the upper part of the storage area of the tank has a large hydrogen content due to the high content of colloidal hydrogen, and conversely, electrolytic alkaline water taken out from the lower part of the storage area of the tank is colloidal Since the content of hydrogen in the form is small or not present at all, the content of hydrogen is smaller than that of electrolytic alkaline water taken out from the upper part of the storage area of the tank.
[0007]
In order to eliminate the residual colloidal hydrogen and obtain an electrolytic alkaline water having a stable content of hydrogen, the means adopted by the present invention is an electrolytic alkaline water containing colloidal hydrogen generated by an electrolytic water generator. Is a method for removing colloidal hydrogen by pumping water with a pump.
[0008]
In the present invention according to claim 2, since the colloidal hydrogen is removed by pressurizing the electrolytic alkaline water with a pump, the colloidal hydrogen has a very small amount or no colloidal hydrogen and a stable hydrogen content. Electrolytic alkaline water can be pumped.
[0009]
Means adopted by the present invention according to claim 3 for selectively extracting electrolytic alkaline water containing a large amount or a small amount of hydrogen is an electrolytic aqueous solution for producing electrolytic alkaline water containing colloidal hydrogen. Generating device, a tank for storing the electrolytic alkaline water supplied from the electrolytic water generating device, and an extraction path for individually extracting the electrolytic alkaline water from each of the upper and lower portions of the storage area of the tank, To remove the electrolytic alkaline water.
[0010]
According to the third aspect of the present invention, electrolytic alkaline water having a high content of colloidal hydrogen is obtained by extracting electrolytic alkaline water from the upper part of the storage area of the tank by an extraction path, and the lower part of the storage area of the tank is obtained. The electrolytic alkaline water having low or no colloidal hydrogen content can be obtained by extracting the electrolytic alkaline water from the wastewater in the extraction path. Electrolyzed alkaline water taken out from the upper part of the storage area of the tank has a large hydrogen content due to the high content of colloidal hydrogen, and conversely, electrolytic alkaline water taken out from the lower part of the storage area of the tank is colloidal Since the hydrogen content is low or no, the hydrogen content is lower than that of the electrolytic alkaline water taken out from the upper part of the storage area of the tank.
[0011]
The means adopted by the present invention according to claim 4 for storing electrolytic alkaline water containing a large amount of hydrogen is an electrolytic water generating apparatus for generating electrolytic alkaline water containing colloidal hydrogen and supplied from the electrolytic water generating apparatus. A primary tank that stores the electrolytic alkaline water to be supplied, and a secondary tank that is connected to an upper portion of the storage area of the primary tank via an extraction path and stores the electrolytic alkaline water supplied from the primary tank. And a device for taking out electrolytic alkaline water.
[0012]
According to the present invention as set forth in claim 4, electrolytic alkaline water having a high content of colloidal hydrogen is located at the upper part of the storage area of the primary tank, and the content of the colloidal hydrogen collected at the upper part of the storage area is high. By taking out a large amount of electrolytic alkaline water in the extraction path and storing it in the secondary tank, it is possible to store electrolytic alkaline water with a large hydrogen content in the secondary tank.
[0013]
The means adopted by the present invention according to claim 5 for shortening a period in which the content of hydrogen changes when taking out the alkaline water from the tank is an electrolyzed water generating apparatus for producing electrolytic alkaline water containing colloidal hydrogen. And a tank for storing electrolytic alkaline water supplied from the electrolyzed water generator, the tank having an entrance / exit path and a plurality of storage chambers communicating with the entrance / exit path, and electrolysis supplied from the electrolyzed water generator. Electrolysis wherein alkaline water is sequentially distributed to each of the plurality of storage chambers via the access path, and the electrolytic alkaline water stored in the plurality of storage chambers can be sequentially taken out of each of the storage chambers via the access path. It is a device for taking out alkaline water.
[0014]
According to the fifth aspect of the present invention, when the electrolytic alkaline water having a high content of colloidal hydrogen is supplied to the tank from the electrolytic water generating apparatus, the electrolytic alkaline water is sequentially distributed to each storage chamber through the inlet / outlet passage of the tank. Then, after the supply, the electrolytic alkaline water in each storage chamber can be sequentially taken out through the access path. The electrolytic alkaline water stored in each storage room is located at the upper part of each storage room where a large amount of hydrogen containing a large amount of colloidal hydrogen is gathered, and the content of colloidal hydrogen is lower at the bottom of each storage room. Those having a low or no hydrogen content are gathered and located. Therefore, the amount of hydrogen contained in the electrolytic alkaline water taken out of each storage room to the outside of the tank changes every time the storage room to be taken out changes. However, the fluctuation period can be shortened as compared with a tank having only one storage room.
[0015]
The present invention described in claim 5 may be modified as follows. That is, an electrolyzed water generator for generating electrolyzed alkaline water containing colloidal hydrogen, and a tank for storing the electrolyzed alkaline water supplied from the electrolyzed water generator are provided. A plurality of storage chambers are provided along the direction and communicate with the entrance / exit path, and the electrolytic alkaline water supplied from the electrolytic water generator is sequentially distributed from the lower storage chamber to the upper storage chamber via the entrance / exit path. The apparatus is a device for taking out electrolytic alkaline water that can sequentially take out the electrolytic alkaline water stored in the plurality of storage chambers from the upper storage chamber to the lower storage chamber via the entrance / exit path.
[0016]
Means adopted by the present invention according to claim 6 in order to be able to take out the electrolytic alkaline water having a stable hydrogen content, an electrolytic water generating apparatus for producing electrolytic alkaline water containing colloidal hydrogen, A tank for storing electrolytic alkaline water supplied from the electrolytic water generating apparatus, a stirrer for dispersing colloidal hydrogen for stirring a storage area of the tank, and a discharge path for extracting electrolytic alkaline water from the tank. To remove the electrolytic alkaline water.
[0017]
According to the present invention as set forth in claim 6, the electrolytic alkaline water supplied from the electrolytic water generating apparatus and stored in the tank is stirred by a stirrer for dispersing colloidal hydrogen, and the colloidal water is stored in the whole of the stored electrolytic alkaline water. Since hydrogen is dispersed, electrolytic alkaline water having a stable hydrogen content can be taken out of the tank.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a method and an apparatus for extracting electrolytic alkaline water according to the present invention will be described based on embodiments shown in the drawings.
[0019]
(First Embodiment)
FIG. 1 is a schematic configuration diagram showing a first embodiment of a method and an apparatus for extracting electrolytic alkaline water according to the present invention. An apparatus 1 for extracting electrolytic alkaline water according to the present embodiment includes an electrolytic water generator 2 that generates electrolytic alkaline water containing colloidal hydrogen, and a tank 3 that stores electrolytic alkaline water B supplied from the electrolytic water generator 2. And extraction paths 5 and 6 for individually extracting electrolytic alkaline water from the upper part 4 a and the lower part 4 b of the storage area 4 of the tank 3.
[0020]
The electrolyzed water generator 2 includes an electrolyzer 7, an electrically conductive water supply device 8, and a controller (not shown). The electrolytic cell 7 includes a cathode chamber 11 in which a negative electrode 10 is inserted and an anode chamber 13 in which a positive electrode 12 is inserted, which is divided by an ion-permeable diaphragm 9, and a DC voltage is applied between both electrodes 10, 12. Thus, the conductive water A supplied from the supply device 8 to the two chambers 11, 13 is electrolyzed. The DC voltage applied between the two electrodes 10 and 12 can be appropriately adjusted via a control unit. The DC voltage generated in the cathode chamber 11 and supplied to the tank 3 contains colloidal hydrogen and contains predetermined colloidal hydrogen. And ORP (oxidation-reduction potential). The supply device 8 supplies the conductive water A to the electrolytic cell 7 at a set flow rate while keeping the electric conductivity of the conductive water A substantially constant so as to stabilize the pH and ORP of the electrolytic alkaline water B generated in the cathode chamber 11. It has become. In the electrolyzed water generator 2, a water conduit 18 extends from the anode chamber 13 of the electrolysis tank 7 so that the electrolyzed acidic water C generated in the anode chamber 13 can be taken out.
[0021]
The tank 3 has a storage area 4 for storing electrolytic alkaline water therein. The lower area 4b of the storage area 4 communicates with the cathode chamber 11 of the electrolyzed water generator 2 through a water conduit 15, and the tank 3 has an upper area 4a. The inflow port 5a of the upper discharge path 5 is opened, and the inflow port 6a of the lower discharge path 6 is opened in the lower storage area 4b. The electrolytic alkaline water B containing colloidal hydrogen generated in the cathode chamber 11 is supplied to the tank 3 via the water conduit 15 and is temporarily stored in the storage area 4. A part of the electrolytic alkaline water B stored in the storage area 4 is taken out of the tank from the upper part 4a of the storage area through the upper take-out path 5, and the remaining part is taken out of the lower part 4b of the storage area through the lower take-out path 6. It is taken out of the tank. Each of the take-out paths 5, 6 is provided with on-off valves 16, 17 for adjusting the take-out amount, so that the ratio of the flow rate taken out from the upper part 4a and the lower part 4b of the tank storage area 4 can be adjusted. The size of the storage area 4 of the tank 3 is set to be larger than the capacity obtained by multiplying the flow rate of the electrolytic alkaline water B supplied from the electrolyzed water generator 2 by the residence time, and a predetermined residence time (for example, 5 minutes) is set. Secured.
[0022]
The electrolytic alkaline water B stored in the storage area 4 of the tank 3 is located such that colloidal hydrogen gathers at the upper area 4a of the storage area, and the amount of colloidal hydrogen decreases toward the lower area 4b of the storage area. In the lower part 4b, colloidal hydrogen is very small or absent. The respective ranges of the storage area upper part 4a and the storage area lower part 4b vary depending on the capacity of the electrolyzed water generating apparatus 2 for generating the electrolytic alkaline water B containing colloidal hydrogen and the size of the tank 3. When the diameter of 4 is 70-100 mm and the height of the storage area 4 is 400-500 mm, the upper area 4a of the storage area is in a range from the water surface 4c to the depth of 20-40mm, and the lower area 4b of the storage area is lower than the bottom 4d. The range is from the position 20 to 40 mm above to the bottom surface 4d.
[0023]
The upper take-out path 5 of the tank 3 raises and lowers the inflow port 5a in conjunction with the case where the inflow port 5a is fixed at a predetermined height position and the rise and fall of the water surface 4c of the tank storage area 4. There are cases. In the case of raising and lowering the inflow port 5a, although not shown, for example, the inflow side is formed of a flexible tube, and a float is attached to the vicinity of the inflow port 5a which can be moved up and down, so that the rising and falling water surface 4c is formed. The inflow port 5a is always located below, so that the electrolytic alkaline water can flow into the inflow port 5a. As described above, when the position of the inlet 5a of the upper outlet passage 5 is configured to be lowered in conjunction with the water surface 4c of the tank storage area 4, the on-off valves 16, 17 are adjusted to adjust the electrolytic alkaline water Ba, Bb. Can be used while maintaining the ORP constant by mixing at a constant ratio, and a large amount of the electrolytic alkaline water Ba, Bb stored in the storage area 4 can be used.
[0024]
Next, a method for removing electrolytic alkaline water using the electrolytic alkaline water removing device 1 will be described. This extracting method is intended to selectively extract electrolytic alkaline water having a high or low hydrogen content. The electrolytic alkaline water B containing colloidal hydrogen generated by the electrolytic water generating apparatus 2 Is temporarily stored in the tank 3 and the electrolytic alkaline water having a high content of colloidal hydrogen is naturally collected and positioned in the upper portion 4a of the stored storage area 4, and the lower portion 4b has a low content of the colloidal hydrogen or With no electrolytic alkaline water positioned, these two electrolytic alkaline waters Ba and Bb are individually taken out by the extraction paths 5 and 6. In this way, by extracting from the upper part 4a of the tank storage area 4 by the upper extraction passage 5, electrolytic alkaline water Ba having a large content of colloidal hydrogen and a large hydrogen content can be obtained. By extracting the colloidal hydrogen from the lower portion 4a of the lower portion 4 through the lower extraction channel 6, electrolytic alkaline water Bb having a small or no colloidal hydrogen content and a small hydrogen content can be obtained. In addition, in order to take out the electrolytic alkaline water Ba and Bb from the tank storage area 4, there is a case where it is performed simultaneously in both the upper discharge path 5 and the lower discharge path 6 and a case where only one of them is used depending on the use. .
[0025]
The electrolytic alkaline water Ba taken out from the upper take-out passage 5 has a high content of colloidal hydrogen and therefore has a high hydrogen content and a low ORP. Since the water Bb has a low or no colloidal hydrogen content, the water Bb has a lower hydrogen content and a higher ORP than that extracted in the upper extraction passage 5. As an example, the electrolytic alkaline water Ba taken out in the upper take-out passage 5 has a pH of 10.1 to 10.2 and an ORP of -730 to -700 mV, whereas the electrolytic alkaline water Ba taken out in the lower take-out passage 6 Bb has a pH of 10.1 to 10.2 and ORP of 0 to +40 mV.
[0026]
(Second embodiment)
FIG. 2 is a schematic configuration diagram showing a second embodiment of the apparatus for extracting electrolytic alkaline water according to the present invention. The take-out device 21 according to the present embodiment is largely different from the take-out device 1 according to the first embodiment (see FIG. 1) in that the take-out device 21 includes a primary tank 3 and a secondary tank 23 as tanks. This is the point that the secondary tank 23 is connected to the storage area upper part 4a via the takeout path 5. The configuration other than this difference is substantially the same as that of the unloading device 1, and the same reference numerals indicate the same components and the like.
[0027]
The secondary tank 23 guides the electrolytic alkaline water Ba having a large content of colloidal hydrogen collected in the storage area upper part 4a of the primary tank 3 through the extraction path 5 and stores it in the internal storage area. . The secondary tank 23 has an outlet 25 with an on-off valve 26 extending from the lower portion or the bottom of the storage area, so that the alkaline water Ba containing a large amount of colloidal hydrogen can be taken out at any time.
[0028]
(Third embodiment)
FIG. 3 is a schematic configuration diagram showing a third embodiment of the apparatus for extracting electrolytic alkaline water according to the present invention. The take-out device 31 according to the present embodiment is significantly different from the take-out device 1 according to the first embodiment (see FIG. 1) in that a tank 33 for storing electrolytic alkaline water supplied from the electrolytic water generation device 2 is provided. The structure is as follows. The configuration other than this difference is substantially the same as that of the unloading device 1, and the same reference numerals indicate the same components and the like.
[0029]
In order to use all or most of the electrolytic alkaline water B stored in the storage area 4 of the tank 3 of the first embodiment shown in FIG. As described above, the position of the inlet 5a of the upper take-out passage 5 is configured to be moved up and down in conjunction with the water surface 4c of the tank storage area 4, and the opening degrees of the two on-off valves 16 and 17 need to be adjusted. Sometimes inconvenient. Therefore, in the present embodiment, when the electrolytic alkaline water stored in the storage area 33a of the tank 33 is taken out, the period in which the hydrogen content fluctuates can be shortened.
[0030]
The tank 33 includes an entrance / exit path 34 and a plurality of storage chambers 35 communicating with the entrance / exit path 34, and supplies the electrolytic alkaline water supplied from the electrolytic water generation device 2 to each of the plurality of storage chambers 35 via the entrance / exit path 34. The electrolytic alkaline water which is sequentially distributed and stored in the plurality of storage chambers 35 can be sequentially taken out of each of the storage chambers via the access path 34. The tank 33 according to the present embodiment includes, in its interior, an access path 34 extending in the up-down direction and a plurality of storage chambers 35 provided along the up-down direction and communicating with the access path 34, and supplied from the electrolyzed water generator 2. The electrolytic alkaline water to be distributed can be sequentially distributed from the lower storage chamber 35 to the upper storage chamber 35 via the access path 34, and the electrolytic alkaline water stored in the plurality of storage chambers 35 can be distributed via the access path 34. It can be sequentially taken out from the upper storage chamber 35 to the lower storage chamber 35. The tank 33 is opened such that the outlet 15 b of the water conduit 15 extending from the electrolyzed water generator 2 communicates with the lower part of the inlet / outlet 34, and the colloidal hydrogen generated in the cathode chamber 11 of the electrolyzed water generator 2 is opened. Is introduced into the lower part of the inlet / outlet path 34, and the inlet 38a of the outlet path 38 with the on-off valve 39 is opened so as to communicate with the lower part of the tank or the bottom part of the tank. The electrolytic alkaline water stored in the chamber 35 can be taken out of the tank.
[0031]
The tank 33 divides, for example, upper and lower storage chambers 35, 35 with a partition plate 36 that is inclined upward as the distance from the entrance / exit path 34 is increased, and the upper part 35 a of the storage part of each storage chamber 35 that is inclined upward and the outside of the tank. It communicates with the ventilation pipe 37 so that the electrolytic alkaline water B can be put in and out of the entire inside of each storage section through the access path 34 via the lower portion 35b of the storage section of each storage chamber 35. The inclined partition plate 36 forms the bottom surface of the storage room 35 located above, and forms the ceiling surface of the storage room 35 located below. The vent pipe 37 is for taking in and out air for replacing electrolytic alkaline water with the outside of the tank when electrolytic alkaline water is taken in and out of each storage chamber 35. The ventilation pipe 37 includes a collecting pipe 37a having an opening / closing port 37a-1, and a branch pipe 37b communicating the collecting pipe 37a with the upper portion 35a of each storage chamber 35. Each branch pipe 37b forms an inverted V-shaped trap or the like so that the electrolytic alkaline water Ba does not escape from the upper portion 35a of each storage chamber 35. The ventilation pipe 37 may be partially or entirely provided inside the main body of the tank 33, and the air supply / exhaust port 37 a-1 may be communicated with the outside of the tank 33.
[0032]
In the tank 33, the ventilation pipe 37 can be omitted, and the air vent valve 32 can be provided at the upper end side of each inclined partition plate 36 as shown in FIG. The air vent 32 communicates the adjacent upper and lower storage chambers 35, 35, and releases the air pressurized when the electrolytic alkaline water B enters the lower storage chamber 35 to the upper storage chamber 35. The valve is opened as described above, and is closed when the lower storage chamber 35 becomes full and the entry of the electrolytic alkaline water B into the upper storage chamber 35 starts. The opening and closing of the air vent 32 are automatically performed.
[0033]
The take-out device 31 according to the present embodiment, when the electrolytic alkaline water B having a high content of colloidal hydrogen is supplied from the cathode chamber 11 of the electrolytic water generation device 2 to the tank 33 through the water channel 15, the tank 33 The electrolytic alkaline water B is sequentially distributed to the respective storage chambers 35 via the entrance / exit path 34 and stored in the respective storage chambers 35. Each of the storage chambers 35 storing the electrolyzed alkaline water B in a full state is located at the upper part 35a of the storage section which is inclined upward, in which the electrolyzed alkaline water Ba having a large content of colloidal hydrogen and a large hydrogen content is naturally collected. Then, in the lower portion 35b of the storage section of each storage chamber 35, the electrolytic alkaline water Bb with a small or no colloidal hydrogen content and a small hydrogen content is collected and located. The stored electrolytic alkaline water can be sequentially extracted from the upper storage chamber 35 to the lower storage chamber 35 by opening the on-off valve 39 of the extraction path 38. As described above, the electrolytic alkaline water extracted from each of the storage chambers 35 in a full state to the outside of the tank via the entrance / exit path 34 and the extraction path 38 is replaced by the electrolytic alkaline water Bb and Ba each time the storage chamber 35 to be extracted changes. Although the hydrogen content fluctuates, the storage chamber without a plurality of storage chambers 35 can shorten the cycle in which the hydrogen content fluctuates as compared with a single tank, so that it supplies electrolytic alkaline water with a relatively stable reducing power. can do.
[0034]
(Fourth embodiment)
FIG. 5 is a schematic configuration diagram showing a fourth embodiment of the apparatus for extracting electrolytic alkaline water according to the present invention. The take-out device 41 according to the present embodiment is greatly different from the take-out device 1 according to the first embodiment (see FIG. 1) in that a tank 43 for storing electrolytic alkaline water supplied from the electrolytic water generation device 2 is provided. The structure is as follows. The configuration other than this difference is substantially the same as that of the unloading device 1, and the same reference numerals indicate the same components and the like.
[0035]
The tank 43 includes a stirrer 45 for dispersing colloidal hydrogen that stirs the internal storage area 43a, and an extraction path 46 with an on-off valve 47 for extracting electrolytic alkaline water B from the lower or bottom of the storage area 43a. As the stirrer 45, a rotary blade type or the like in which a stirring blade 45c is attached to a tip of a rotary shaft 45b rotated by a motor 45a is selected.
[0036]
The removal device 41 according to the present embodiment stores the electrolytic alkaline water B supplied from the cathode chamber 11 of the electrolytic water generating device 2 through the water conduit 15 in the tank 43, and stores the electrolytic alkaline water B stored in the tank 43. Since B is stirred by the stirrer 46 to disperse the colloidal hydrogen in the electrolytic alkaline water throughout the tank storage area 43a, the electrolytic alkaline water B having a stable hydrogen content is taken out of the tank 43 through the take-out path 46. Can supply electrolytic alkaline water B having a stable reducing power.
[0037]
(Fifth embodiment)
FIG. 6 is a schematic configuration diagram showing a fifth embodiment of a removal apparatus for performing the method for removing electrolytic alkaline water according to the present invention. The take-out device 51 according to the present embodiment includes a primary tank 53 for storing electrolytic alkaline water containing colloidal hydrogen generated in the cathode chamber 11 of the electrolytic water generation device 2, and an electrolytic alkaline water stored in the primary tank 53. An extraction path 55 with a pump 56 for extraction is provided with a secondary tank 57 for storing electrolytic alkaline water pumped by the pump 56. The secondary tank 57 is provided with an extraction passage 58 with an on-off valve 59 so that the electrolytic alkaline water Bb can be extracted from the lower portion or the bottom of the storage area 57a therein. Note that the electrolyzed water generator 2 is substantially the same as that of the first embodiment, and a description thereof will be omitted.
[0038]
The pump 56 removes colloidal hydrogen contained in the electrolytic alkaline water by pressurizing the electrolytic alkaline water, and is a centrifugal pump or a gear that can obtain a sufficient pressure to remove the colloidal hydrogen. A pump or the like is used. When the electrolytic alkaline water pumped by the pump 56 is used as it is, the secondary tank 57 is omitted.
[0039]
By using the extraction device 51 according to the present embodiment, the alkaline water containing colloidal hydrogen generated by the electrolytic water generation device 2 is pumped by the pump 56 to remove the colloidal hydrogen and remove the colloidal hydrogen. Thus, it is possible to obtain electrolytic alkaline water Bb having a stable content of hydrogen and free of hydrogen, and to supply electrolytic alkaline water having a stable reducing power.
[0040]
【The invention's effect】
The method for removing electrolytic alkaline water according to the present invention according to claim 1 can selectively remove electrolytic alkaline water having a large or small amount of hydrogen, and therefore, electrolytic alkaline water corresponding to the reducing power required for various uses. Can be supplied.
[0041]
The method for removing electrolytic alkaline water according to the present invention according to claim 2 can provide electrolytic alkaline water having a stable content of hydrogen without colloidal hydrogen, and can supply electrolytic alkaline water having a stable reducing power. it can.
[0042]
Since the apparatus for removing electrolytic alkaline water according to the present invention according to claim 3 can selectively remove electrolytic alkaline water having a large or small amount of hydrogen, the electrolytic alkaline water according to the reducing power required for various uses is obtained. Can be supplied.
[0043]
According to the fourth aspect of the present invention, the apparatus for removing electrolytic alkaline water according to the present invention stores electrolytic alkaline water having a large hydrogen content in the secondary tank, so that it is possible to supply electrolytic alkaline water having a high reducing power.
[0044]
The apparatus for removing electrolytic alkaline water according to the present invention according to claim 5 can shorten the cycle in which the content of hydrogen fluctuates when removing electrolytic alkaline water from a tank as compared with a tank without a plurality of storage chambers. Can supply relatively stable electrolytic alkaline water.
[0045]
The apparatus for extracting electrolytic alkaline water according to the present invention according to claim 6 can extract electrolytic alkaline water having a stable hydrogen content, and therefore can supply electrolytic alkaline water having a stable reducing power.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing a first embodiment of a method and an apparatus for extracting electrolytic alkaline water according to the present invention.
FIG. 2 is a schematic configuration diagram showing a second embodiment of an apparatus for extracting electrolytic alkaline water according to the present invention.
FIG. 3 is a schematic configuration diagram showing a third embodiment of a device for removing electrolytic alkaline water according to the present invention.
FIG. 4 is a partially broken configuration diagram showing another mode of the tank according to the third embodiment.
FIG. 5 is a schematic configuration diagram showing a fourth embodiment of a device for removing electrolytic alkaline water according to the present invention.
FIG. 6 is a schematic configuration diagram showing a fifth embodiment of a take-out device for carrying out a method of taking out electrolytic alkaline water according to the present invention.
[Explanation of symbols]
2 electrolyzed water generator, 3 (33, 43) tank, 4 tank storage area, 4a upper part, 4b lower part, 5 (6, 46) extraction path, 23 secondary tank, 34 in / out Road, 35 ... storage room, 45 ... stirrer, 56 ... pump

Claims (6)

Electrolyzed alkaline water containing colloidal hydrogen generated by the electrolyzed water generator is stored in a tank. Electrolyzed alkaline water with a high content of colloidal hydrogen is located above the storage area, and colloidal hydrogen is located below it. A method for extracting electrolytic alkaline water in which upper and / or lower electrolytic alkaline water is individually taken out by locating electrolytic alkaline water having a content of less or no as compared with that located in the upper part . A method for removing electrolytic alkaline water, comprising removing colloidal hydrogen by pumping electrolytic alkaline water containing colloidal hydrogen generated by an electrolytic water generator with a pump. An electrolyzed water generator for generating electrolyzed alkaline water containing colloidal hydrogen, a tank for storing electrolyzed alkaline water supplied from the electrolyzed water generator, and an electrolyzed alkaline water from each of the upper and lower storage areas of the tank. And an extraction path for individually extracting water. An electrolyzed water generator for generating electrolyzed alkaline water containing colloidal hydrogen, a primary tank for storing the electrolyzed alkaline water supplied from the electrolyzed water generator, and a take-out path above the storage area of the primary tank A device for taking out electrolytic alkaline water, comprising a secondary tank connected to store electrolytic alkaline water supplied from the primary tank. An electrolyzed water generator for generating electrolyzed alkaline water containing colloidal hydrogen; and a tank for storing the electrolyzed alkaline water supplied from the electrolyzed water generator. And sequentially distributes the electrolytic alkaline water supplied from the electrolytic water generation device to each of the plurality of storage chambers via the entrance / exit path, and supplies the electrolytic alkaline water stored in the plurality of storage chambers to the entrance / exit path. A device for taking out electrolytic alkaline water, which can be taken out of each of the storage chambers sequentially through the storage device. An electrolyzed water generator for generating electrolyzed alkaline water containing colloidal hydrogen, a tank for storing the electrolyzed alkaline water supplied from the electrolyzed water generator, and a stirrer for colloidal hydrogen dispersion for stirring the storage area of the tank. An extraction path for extracting electrolytic alkaline water from the tank.

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