PROCESS AND SYSTEM FOR PRODUCING HYDROGENATED DRINKING WATER

Abstract

A process and system for producing a hydrogenated drinking water has a reverse osmosis filter, an ionizer and a power supply. The reverse osmosis filter has an inlet on one side thereof and first and second outlets on an opposite side thereof. The first outlet is adapted to pass a permeate from the reverse osmosis filter. The second outlet is adapted to pass brine from the reverse osmosis filter. The ionizer is in fluid communication with the reverse osmosis filter. The ionizer has a first inlet connected to the first outlet of the progress osmosis filter. The ionizer has a second inlet connected to the second outlet of the reverse osmosis filter. The power supply is connected to the ionizer so as to electrolysize the brine and the permeate.

Claims

1. A process for producing hydrogenated drinking water, the process comprising: passing water into a reverse osmosis filter so as to produce a permeate and a brine; passing the permeate from the reverse osmosis filter to an ionizer; passing at least a portion of the brine from the reverse osmosis filter to the ionizer; and ionizing the permeate and the at least a portion of the brine so as to produce an oxygenated water output and a hydrogenated drinking water output.

2. The process of claim 1, the ionizer having a first compartment and a second compartment, the step of passing the permeate comprising: passing the permeate into the first compartment and to the second compartment.

3. The process of claim 2, the step of passing at least a portion of the brine comprising: passing the at least a portion of the brine into only the second compartment.

4. The process of claim 3, further comprising: mixing the permeate and the at least a portion of the brine in the second compartment.

5. The process of claim 2, wherein the ionizer has a first conductor in the first compartment and a second conductor in the second compartment, the first conductor passing a negative charge, the second conductor passing a positive charge.

6. The process of claim 5, the step of ionizing comprising: applying the positive charge to the second conductor and the negative charge to the first conductor so as to ionize the permeate in the first compartment and the at least a portion of the brine in the second compartment such that hydrogen molecules migrate from the second compartment to the first compartment.

7. The process of claim 6, wherein the ionizer has a membrane positioned between the first compartment and the second compartment.

8. The process of claim 7, wherein the step of ionizing further comprises: migrating the hydrogen molecules from the second compartment through the membrane and into the first compartment while blocking oxygen molecules from entering the first compartment.

9. The process of claim 2, wherein the permeate flows under a first pressure from the reverse osmosis filter to the first and second compartments, the at least a portion of the brine flowing under a second pressure to the second compartment of the ionizer, wherein the first pressure is greater than the second pressure.

10. The process of claim 1, the step of passing at least a portion of the brine comprising: discharging the brine from the reverse osmosis filter along a line toward an outlet, the line having a valve thereon; and moving the valve so as to direct the at least a portion of the brine toward the ionizer and so as to direct the remaining portion of the brine toward a drain.

11. A system for producing a hydrogenated drinking water, the system comprising: a reverse osmosis filter having an inlet on one side thereof and a first outlet on an opposite side of said reverse osmosis filter and a second outlet on the opposite side of said reverse osmosis filter, the first outlet adapted to pass a permeate from said reverse osmosis filter, the second outlet adapted to pass a brine from said reverse osmosis filter; an ionizer in fluid communication with said reverse osmosis filter, said ionizer having a first inlet connected to the first outlet of said reverse osmosis filter, said ionizer having a second inlet connected to the second outlet of said reverse osmosis filter; and a power supply in fluid communication with said reverse osmosis filter, said power supply connected to the ionizer so as to electrolysize the brine and the permeate in said ionizer, said ionizer having a first outlet adapted to pass an electrolysized hydrogenated water from said ionizer and a second outlet adapted to pass an oxygenated water from said ionizer, said power supply providing a positive current and a negative current to the brine and to the permeate, respectively.

12. The system of claim 11, wherein the second outlet has a valve thereon, the valve being movable to pass at least a portion of the brine from said reverse osmosis filter to said ionizer.

13. The system of claim 11, wherein said ionizer has a third inlet, the third inlet being in fluid communication with said reverse osmosis filter such that a portion of the permeate enters the first inlet and another portion of the permeate enters the third inlet.

14. The system from of claim 11, wherein said ionizer has a first outlet adapted to pass hydrogenated drinking water from said ionizer and a second outlet adapted to pass the oxygenated water from said ionizer.

15. The system of claim 11, said ionizer comprising: a container having an interior volume; a first compartment formed within said container; a second compartment formed within said container; and a membrane positioned between the said first compartment and said second compartment, wherein a first conductor is positioned in said first compartment and a second conductor is positioned in said second compartment.

16. The system of claim 15, wherein the first inlet communicates with said first compartment such that permeate from said reverse osmosis filter flows into said first compartment, the second inlet communicating with said second compartment such that the brine flows into said second compartment.

17. The system of claim 16, wherein said ionizer has a third inlet, the third inlet being in communication with the first outlet of said reverse osmosis filter, the third inlet being in communication with said second compartment such of the portion of the permeate flows into said second compartment.

18. The system of claim 15, wherein the first conductor conducts a negative charge from said power supply, the second conductor conducting a positive charge from said power supply such that the hydrogen molecules migrate through said membrane from said second compartment to said first compartment.

19. The system of claim 15, said membrane being a proton exchange membrane.

20. The system of claim 19, said first compartment having a hydrogenated drinking water outlet, said second compartment having an oxygenated water outlet.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0041] FIG. 1 is a block diagram showing the operation of a system for producing hydrogenated water in accordance with the prior art.

[0042] FIG. 2 is a block diagram showing the process and system of the present invention for producing a hydrogenated drinking water output.

[0043] FIG. 3 is a cross-sectional view showing the configuration of the ionizer of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0044] Referring to FIG. 2, there shown the system 30 for the production of a hydrogenated water in accordance with the preferred embodiment of the present invention. System 30 includes a water supply 32. Water supply 32 can be in the nature of a tap water supply. A prefilter 34 is connected to the water supply 32 by a line 36. Pretreatment filter 34 can be in the nature of an activated carbon filter, a screen, a sand filter, or other device wherein particulate impurities in the water supplied from the water supply 32 are separated from the flow passing from the prefilter 34 into the activated carbon filter 38. This water will pass along line 40 into the activated carbon filter 38. The activated carbon filter 38 has a bed of activated carbon. This activated carbon filter 38 serves to remove impurities through adsorption. It removes some chlorines, particulates such a sediment, and volatile organic compounds. It does not effectively filter inorganics, fluoride, cyanide. The water passing through line 42 to reverse osmosis filter 44 will contain a certain amount of total dissolved solids (TDS). These total dissolved solids can include minerals, salts, metals, cations or anions. It also can include inorganic salts, calcium, magnesium, potassium, sodium, bicarbonates, chlorides and sulfites. Typically, a pump will be provided along line 42 or in cooperation with line 42 so as to apply a pressure of approximately 80 p.s.i. to the flow to the reverse osmosis filter 44.

[0045] The reverse osmosis filter 44 completely filters the impurities from the water. In particular, the reverse osmosis filter 44 will remove inorganics and fluorides. Generally, only the pure water molecules will get through and pass as permeate 46. The permeate 46 passes to an ionizer 48. Since the permeate 46 is pure water, it is too clean for the ionizer. There are no ions, minerals or salts for proper charging by the ionizer 48. The absence of such total dissolved solids from the permeate 46 will significantly reduce conductivity within the ionizer 48.

[0046] As can be seen in FIG. 2, the permeate 46 passes outwardly of the reverse osmosis filter 44 through a first outlet 45 into line 47. Ultimately, line 47 will divide into a first portion 49 and a second portion 51 so as to deliver the permeate 46 into a first compartment 53 and a second compartment 55 of ionizer 48. Specifically, portion 49 of line 47 will deliver some of the permeate into the first compartment 53. The portion 51 of line 47 will deliver this permeate into the ionizer 55. The ionizer 47 is shown in greater detail in connection with FIG. 3 herein.

[0047] Importantly, the permeate 46 exiting outlet 45 from reverse osmosis filter 44 is essentially pure water containing no contaminants, salts, or other dissolved solids. As such, it will contain virtually no ions with which to electrolysize the solution within the compartment 57 of ionizer 48. Any attempt to electrolysize such ions within the ionizer 48 would be extremely ineffective in achieving a proper hydrogenated drinking water output. As such, in order to allow the electrolysis process to be conducted properly within ionizer 48, it is necessary to introduce the salts and ions into the ionizer. In the present invention, this is achieved by introducing at least a portion of the brine 42 from outlet 50 of the reverse osmosis filter 44.

[0048] In FIG. 2, it can be seen that the permeate 52 is delivered along a line to a valve 59. Valve 59 is a three-way valve that can be moved into a position so that a portion of the brine 52 passes into line 61 and another portion of the brine 52 flows to outlet 63. Outlet 63 will assure that the unused portion of the highly contaminated and salty brine is delivered to a drain for disposal. The remaining portion of the highly salted and contaminated brine 52 will flow along line 61 so as to be discharged into a second inlet 65 into the second compartment 55 of ionizer 48. As such, the highly salted and contaminated brine 52 can mix with the permeate 46 within the compartment 55 of the ionizer 48. The result is that the very pure permeate will only reside in the first compartment 53. The mixture of the very pure permeate and the highly salted and contaminated brine 52 will reside in the second compartment 55. As such, the second compartment 55 will contain the necessary ions so as to effect the electrolysis process.

[0049] A membrane 69 is positioned between the first compartment 53 and the second compartment 55. The membrane 69 is a proton exchange membrane, such as that manufactured by DuPont under the trademark NAFION?. This proton exchange membrane 69 assures that only hydrogen molecules migrate through the membrane 69 from the second compartment 55 into the first compartment 53 during the electrolysis process. As such, membrane 69 provides a mechanical barrier against the migration of oxygen and contaminants from the second compartment 55 into the first compartment 53.

[0050] Additionally, and furthermore, the permeate 46 will flow through line 47 and into the first compartment 53 and the second compartment 55 under a significant amount of pressure. In contrast, the brine 52 will flow through line 61 into inlet 65 and into the second compartment 55 under much less pressure. Since the fluid pressure within the first compartment 53 is greater than the fluid pressure within the second compartment 55, this pressure differential will resist any flow from the second compartment 55 into the first compartment 53. Once again, this assures that contamination of the water within the first compartment 53 is avoided since this presents a pneumatic barrier to the fluid flow from the second compartment 55 to the first compartment 53. As such, the present invention absolutely assures that the hydrogenated drinking water from the first compartment 53 is free of contamination.

[0051] The ionizer 48 includes a first outlet 71 and a second outlet 73. The first outlet 71 passes the hydrogenated drinking water from the first compartment 53. The second outlet 73 passes the oxygenated water (along with its contaminants) outwardly of the second compartment 55. The oxygenated water and the contaminants can be disposed of in any desired manner.

[0052] The process and system of the present invention, as shown in FIG. 2, achieve significant advantages over the prior art. First, the present invention allows the use of reverse osmosis for the filtering of the tap water 32. As such, the reverse osmosis filter 44 effectively removes all of the contaminants and total dissolved solids from the tap water. This extremely pure water will pass as a pure permeate 46 to the first compartment 53 and the second apartment 55 of the ionizer 48. As such, it is assured that very pure water will reside in the first compartment 53.

[0053] It is important for the present invention to avoid the waste of water and avoid the addition of expensive minerals and other substances for the purposes of enhancing the electrolytic reaction within the ionizer 48. As such, the present invention passes the highly salted and contaminated brine 52 from the reverse osmosis filter 44 into the second compartment 55 of the ionizer 48. The membrane 69 assures that the highly salted and contaminated brine 42 will not migrate into the pure water within the first compartment 53. Additionally, the pressure differential between the pure water in first compartment 53 and the contaminated water in second compartment 55 will assure (by hydraulic means) that there is no flow of contaminated water from the second compartment 55 into the first compartment 53. Since the brine from the reverse osmosis process is utilized in the present invention, there is no need to add minerals so as to effect the electrolysis process. The minerals are contained in the tap water that is originally filtered by the reverse osmosis filter 44. Additionally, since the brine 52 it is highly salted, this will assure that the electrolysis process is carried out very quickly and with a minimal amount of electricity. Ultimately, after the electrolysis process is carried out, the highly contaminated and highly salted oxygenated water can be properly disposed. Unlike the prior art, approximately 75% of the water is preserved in the process of the present invention in comparison with the 50% of water in the prior art. Since the brine is highly concentrated with salts, the footprint of the ionizer can be very small for the carrying out of the hydrogenation of the drinking water.

[0054] The ionizer 48 is particularly shown in FIG. 3. Ionizer 48 includes a container 75 having an interior volume 77. The membrane 69 is positioned between the first compartment 53 and the second compartment 55. In particular, it can be seen that the permeate 46 will pass along line 47 into portions 49 and 51 into the first compartment 53 in the second compartment 55. This permeate is highly purified water with minimal salts. The brine, on the other hand, passes along line 61 into the inlet 65 of the second compartment 55. As such, the second compartment 55 will contain both the highly pure permeate and the highly salted and contaminated brine 52.

[0055] FIG. 3 shows that there is a first conductor 81 positioned in the first compartment 53 and a second conductor 83 positioned in the second compartment 55. The first conductor 51 will pass a negative charge from power supply 85 into the first compartment 53. The second conductor 83 will pass a positive charge from power supply 85 into the second compartment 55. The charging of the first conductor 81 and second conductor 83 will charge the salts within the brine 52 within the second compartment 55 so as to cause the hydrogen molecules to migrate toward and through the membrane 69 into the first compartment 53. Ultimately, in order to create the necessary electrical conductivity between the fluids in the first compartment 53 and second compartment 55, the surfaces of the membrane 69 will need to be soaked with the respective fluids. Since the membrane 69 is a proton exchange membrane, only hydrogen molecules can migrate from the highly salted and contaminated water within the second compartment 55 to the first compartment 53. As such, only hydrogen molecules will bubble through and dissolve in the water in the first compartment 53. Ultimately, this hydrogenated drinking water can be discharged through outlet 71 for consumption by a user. The residual oxygenated water will pass through outlet 73 for disposal.

[0056] The foregoing disclosure and description of the invention is illustrative and explanatory thereof. Various changes in the details of the illustrated construction can be made within the scope of the appended claims without departing from the true spirit of the invention. The present invention should only be limited by the following claims and their legal equivalents