JP2009298714A - Negative ion-generating solution and negative ion-generating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a negative ion-generating solution and a negative ion-generating device that can generate a negative ion having a comparatively long life in the air and also can keep a silver ion stable in a solution before atomizing containing the silver ion and an organic germanium. <P>SOLUTION: The negative ion-generating solution that can generate a negative ion by atomizing using an atomizer, contains the silver ion, the organic germanium and a terpene-based fragrant substance dissolved in an aqueous solvent. The negative ion-generating device that can generate a negative ion by atomizing a negative ion-generating solution, uses the negative ion-generating solution containing the silver ion, the organic germanium and a terpene-based fragrant substance dissolved in an aqueous solvent. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a negative ion generation solution and a negative ion generation apparatus.

  Conventionally, it has been known that negative ions generated using the Leonard effect or the like can cause an antioxidant action or a deodorizing effect on the human body.

In particular, a mist obtained by atomizing water by applying ultrasonic vibration contains a large amount of negative ions, and a negative ion generator using the mist is provided (for example, Patent Documents). 1).
JP 2003-86329 A

  However, since the negative ions generated in this way begin to disappear immediately after being diffused into the air, the amount of negative ions floating in the air rapidly decreases, and fully enjoys the antioxidant and deodorizing effects. There were cases where it was impossible to do so.

  Therefore, in recent years, the present inventors have been able to extend the lifetime of negative ions floating in the air by adding silver ions and organic germanium to water and spraying this preparation liquid with ultrasonic vibration. I found it possible.

  However, the silver ions in the preparation liquid are destabilized by coexisting with organic germanium, and cannot be produced as a negative effect when negative ions are deposited or agglomerated and atomized. There was a fear.

  The present invention has been made in view of such circumstances, can generate negative ions having a relatively long life in the air, and further, in a liquid before spraying in which silver ions and organic germanium coexist. Provides a negative ion generating solution and a negative ion generating apparatus capable of stably presenting silver ions.

  In order to solve the above-mentioned conventional problems, in the negative ion generating solution according to the present invention, in the liquid negative ion generating solution that can generate negative ions by spraying with a spraying device, silver ions as an aqueous solvent, Organic germanium and a terpene aromatic substance were included.

  Moreover, in the negative ion production | generation apparatus which concerns on this invention, in the negative ion production | generation apparatus which can generate | occur | produce a negative ion by spraying a liquid negative ion production | generation solution, the said negative ion production | generation solution contains silver ion as an aqueous solvent. It is characterized by containing organic germanium and a terpene aromatic substance.

  Furthermore, the negative ion generator according to the present invention is also characterized by the following points.

(1) A tank that stores the negative ion generation solution, a filter that is disposed at an outlet of the tank and that allows water to flow while filtering the negative ion generation solution, and a negative ion generation solution that has flowed out through the filter. An ultrasonic generation unit that atomizes, and the ultrasonic generation unit has an output of 25 to 40 W.

(2) The filter includes a filter medium filling part, and the filter medium filling part is filled with a rock having a radioactivity of 0.3 to 0.7 microsievert.

  In the negative ion generating solution according to claim 1, since the aqueous solvent contains silver ions, organic germanium, and a terpene aromatic substance, negative ions having a relatively long life can be generated in the air. In addition, silver ions can be stably present in the liquid before spraying in which silver ions and organic germanium coexist.

  In the negative ion production | generation apparatus of Claim 2, the negative ion production | generation apparatus which can generate | occur | produce a negative ion by spraying a liquid negative ion production | generation solution WHEREIN: The said negative ion production | generation solution contains silver ion as an aqueous solvent. Because it contains organic germanium and a terpene-based aromatic substance, it can generate negative ions with a relatively long life in the air, and in the liquid before spraying, where silver ions and organic germanium coexist. In this case, silver ions can be stably present.

  In the negative ion production | generation apparatus of Claim 3, the tank which stores the said negative ion production | generation solution, the filter which is arrange | positioned in the outflow port of the said tank, and water-passes while filtering the said negative ion production | generation solution, The same filter And an ultrasonic generation unit that atomizes the negative ion generation solution that has flowed out through the liquid. Since the ultrasonic generation unit has an output of 25 to 40 W, silver ions and organic germanium are disrupted by ultrasonic vibration. It is possible to disperse both of them in the mist without being biased while preventing them.

  In the negative ion production | generation apparatus of Claim 4, the said filter is equipped with the filter medium filling part, and the filter medium filling part is filled with the rock which has the radioactivity of 0.3-0.7 microsievert; Therefore, it is possible to further improve the negative ion production efficiency, and to give a weak radioactivity to the mist to cause a physiological stimulus (so-called hormesis effect) that exhibits a good action on a living body such as a human. Can do.

  The present invention is characterized in that in a liquid negative ion generating solution capable of generating negative ions by spraying with a spraying device, an aqueous solvent contains silver ions, organic germanium, and a terpene aromatic substance. The negative ion production solution is provided.

  That is, the negative ion production solution according to the present invention contains silver ions and organic germanium in an aqueous solvent, can generate long-lived negative ions, and is added with a terpene aromatic substance to add silver. It is a negative ion generating solution that suppresses the decrease of ions and can be stored for a long period of time.

  Here, the aqueous solvent refers to a solvent containing water, and refers to water alone or a mixed solvent of water and an organic solvent (for example, alcohol such as ethanol).

  Silver ions are not particularly limited, and may be prepared by dissolving silver chloride in an aqueous solvent, or by combining with an organic skeleton or protein, or by forming a silver colloid to form an aqueous solvent. It may be one with improved stability inside.

  This silver ion has been attracting attention as a highly safe sterilizing component in recent years, and has the effect of suppressing the growth of microorganisms in the negative ion production solution and also imparting a sterilizing effect to the sprayed mist. .

  Therefore, the user of this negative ion generating solution is wrapped in a foggy atmosphere, which improves asthma, improves inflammation derived from microorganisms, improves atopic dermatitis, improves xeroderma, and fungal infection of the skin. Effects such as symptom improvement, cold prevention, and influenza prevention can be enjoyed.

  Organic germanium is obtained by bonding germanium atoms to an organic substance and is not particularly limited.

  Terpene-based aromatic substances are 5 carbon atoms hemiterpene, 10 monoterpenes, 15 sesquiterpenes, 20 diterpenes, 25 sesterterpenes, 30 triterpenes, and 40 tetraterpenes. There may be. Specifically, limonene, pinene, or the like can be used.

  In addition, the terpene-based aromatic substance may be a substance purified as in the above-described specific example, and may be added to the negative ion production solution. For example, lemon, orange-derived fruit extract, pine, cedar, cypress, etc. You may make it add as a plant extract obtained from the tree extract obtained from the conifer of this, and a vegetable, a flower, and a medicinal herb.

  As mentioned above, long-life negative ions can be generated by adding silver ions and organic germanium to an aqueous solvent, and long-life negative ions can be generated by adding terpene aromatic substances. However, the preservability of silver ions can be improved.

  In addition to silver ions, organic germanium, and terpene aromatic substances, essential oils or lecithins derived from plants or trees may be added.

  By adding an essential oil derived from a plant or tree, a so-called phytoncide effect is generated, and the user of the negative ion generation solution can enjoy the relaxation effect.

  Further, by adding lecithin, it is possible to easily disperse the hydrophobic terpene-based aromatic substance in the negative ion generation solution while maintaining the storage stability of silver ions.

  In the negative ion generation apparatus according to the present invention, in the negative ion generation apparatus capable of generating negative ions by spraying a liquid negative ion generation solution, the negative ion generation solution includes silver ions and an organic germanium as an aqueous solvent. And a terpene-based aromatic substance.

  Therefore, the user of the negative ion generation device can fully enjoy the effect of negative ions by being surrounded by the fog atmosphere of the negative ion generation solution sprayed from the negative ion generation device.

  The negative ion generation device includes a tank that stores the negative ion generation solution, a filter that is disposed at an outlet of the tank and that passes the water while filtering the negative ion generation solution, and flows out through the filter. An ultrasonic generation unit that atomizes the negative ion generation solution, and the ultrasonic generation unit has an output of 25 to 40 W.

  Therefore, when atomizing the negative ion generation solution, it is possible to prevent silver ions and organic germanium from collapsing due to ultrasonic vibration, and it is possible to extend the lifetime of the negative ions in the air (in the fog).

  In addition, in the course of research conducted to complete the present invention, the inventors of the present invention, the ultrasonic vibration of 25 W or less, the atomization efficiency of silver ions is poor, and the organic germanium is preferentially atomized, It has been found that the concentration of silver ions in the negative ion generation solution stored in the negative ion generation device increases and the concentration balance between silver ions and organic germanium is lost.

  This concentration balance, specifically, the ratio of the number of moles of silver ions to organogermanium is 100 to 100,000: 1 to 10,000, more specifically 0.01 to 10 ppm of silver ions and 0.1 ppb to 1 ppm of organogermanium. If the concentration balance is lost, there is a problem that the life-extending effect of negative ions in the mist is not fully exhibited and the life is shortened.

  Therefore, by setting the output of ultrasonic vibration to 25 W to 40 W, it is possible to atomize while maintaining an appropriate concentration balance between silver ions and organic germanium, and effectively extend the life of negative ions in the fog. Can do.

  On the other hand, if the output is set to 40 W or more, it does not contribute to improvement of the concentration balance any more, but rather, it may induce destabilization or decay of silver ions or organic germanium, which is not preferable.

  It should be noted that the mechanism for extending the life of negative ions in fog by atomizing the negative ion generation solution containing silver ions and organic germanium at the predetermined concentrations has been sufficiently elucidated. It's hard to say.

  However, the present inventors have found that the silver ions are bonded to the semiconducting germanium constituting the organic germanium, and the terpene-based aromatic substance in the negative ion generation solution functions as these binders. It is anticipated that ions and positive ions in the air will be bound to each other and electrically neutralized, and negative ions will have a longer life.

  The filter of the negative ion generation apparatus according to the present invention includes a filter medium filling unit, and the filter medium filling unit may be filled with rock having a radioactivity of 0.3 to 0.7 microsievert.

  That is, in the flow path of the negative ion generation solution that circulates inside the filter, a filter medium filling portion having a space capable of filling the filter medium is formed, and the negative ion generation solution in the tank passes through the filter while contacting the filter medium. I try to leak.

  And as this filter medium, activated carbon, a magnet, a magnetic body, rocks which can elute mineral, rocks which have a radioactivity of 0.3-0.7 microsievert, etc. can be used.

  In particular, by filling rocks with a radioactivity of 0.3-0.7 microsieverts into the filter media filling part, the radiation emitted from the rocks promotes the ionization of the negative ion production solution and improves the generation efficiency of negative ions. be able to.

  In addition, rocks with a radioactivity of 0.3 to 0.7 microsieverts give a weak radioactivity to the aqueous solvent of the negative ion production solution, or elute a small amount of radioactive material in the rock into the negative ion production solution. As a result, a weak radioactivity can be imparted to the fog, and the user of the negative ion generator can enjoy the hormesis effect.

  Further, by using a magnet or a magnetic material as the filter medium, the aqueous solvent constituting the negative ion generation solution can be magnetized to be in the same state as so-called magnetized water.

  Hereinafter, a negative ion generation solution and a negative ion generation apparatus according to the present invention will be described with reference to the drawings. For convenience of explanation, the negative ion generation device will be described first, and then the negative ion generation solution will be described.

[Configuration of negative ion generator]
FIG. 1 shows the appearance of a negative ion generator A according to this embodiment. FIG. 1 (a) is a front view of the negative ion generator A, and FIG. 1 (b) is a right side view of the negative ion generator A. FIG.

  The negative ion generation apparatus A according to this embodiment includes a solution storage unit 10 that stores a negative ion generation solution B, which will be described in detail later, and an apparatus main body 20 that atomizes the negative ion generation solution B taken out from the solution storage unit 10. And a mist blowing unit 30 for ventilating and diffusing the mist of the negative ion generation solution B generated in the apparatus main body 20.

  The solution storage unit 10 includes a hollow tank 11 made of a translucent synthetic resin and formed in a substantially semi-elliptical spherical shape when viewed from the right side, and a grip piece 12 disposed on the top of the tank 11. By inserting and grasping a hand in a space formed between 12 and the upper part of the tank 11, it can be detached from the apparatus main body 20.

  The apparatus main body 20 is provided with an operation unit 21 on a part of its peripheral surface, so that the negative ion generator A can be operated.

  The operation unit 21 includes an operation panel 22 that serves as a decorative board for the entire operation unit 21, and operation buttons 23, 23,... For operating the negative ion generator A disposed on the operation panel 22. And a liquid crystal display unit 24 for displaying the operating state of the negative ion generator A to the user.

  Each of the plurality of operation buttons 23, 23,... Has a function assigned thereto. The power source of the negative ion generator A is switched on / off, the amount of fog generated is adjusted, and the rotation speed of the rotation nozzle 31 described later. So that you can make adjustments.

  Further, the liquid crystal display unit 24 displays the current fog generation amount and the rotation speed of the rotation nozzle 31. The liquid crystal display unit 24 may display the amount of negative ions contained in the generated mist.

  The mist blowing unit 30 includes a cylindrical body 32 that guides the mist generated in the apparatus main body 20 upward and a hollow rotating nozzle 31 disposed at the tip of the cylindrical body 32. The rotating nozzle 31 is configured to be rotatable around a cylindrical body 32.

  In addition, a blower outlet 33 for discharging the mist generated by the negative ion generator A toward the outside air is formed at the tip of the rotary nozzle 31 so that the rotary nozzle 31 rotates while blowing. The mist is discharged from the outlet 33.

  Next, the internal configuration of the negative ion generator A will be described more specifically with reference to FIG. FIG. 2 is an exploded perspective view of the negative ion generator A.

  First, the solution storage unit 10 will be described. A bottom opening (not shown) for replenishing the negative ion production solution B in the tank 11 is provided in the lower part of the tank 11, and is screwed into the bottom opening. A possible filter 13 is arranged.

  That is, the negative ion generating solution B stored in the tank 11 is supplied through the filter 13 when supplied to the apparatus main body 20 side. The structure of the filter 13 will be described later with reference to FIG.

  Next, the apparatus main body 20 will be described. A main body case 40 that functions as a housing of the apparatus main body 20, an operation unit 21 that is fitted into a notch formed on the peripheral surface of the main body case 40, and an upper portion of the main body case 40. A tray 41 that closes the opening.

  Further, in the internal space formed between the main body case 40 and the tray 41, an ultrasonic generation unit 42 that generates ultrasonic waves, and a transformer 43 that performs transformation of electricity supplied to the ultrasonic generation units 42, A blower fan 44 for air-cooling these devices and a fan case 45 for housing the blower fan 44 are provided. The ultrasonic wave generation unit 42 is provided with an ultrasonic transducer 50 that is an ultrasonic wave generation source.

  The tray 41 formed in a substantially tray shape is formed with a storage recess 46 having a substantially circular shape in plan view and an atomization recess 47 having a substantially circular shape in plan view and having a slightly larger radius than the storage recess. Yes.

  In addition, the storage recess 46 and the atomization recess 47 are connected to each other via a communication portion 48, so that the negative ion production solution B that has flowed out of the tank 11 into the storage recess 46 flows into the atomization recess 47. Is formed.

  In addition, a columnar pressing protrusion 49 is disposed at a substantially central portion of the storage recess 46, and when the tank 11 is placed on the apparatus main body 20 (the receiving tray 41), a valve shaft of the filter 13, which will be described later. 61 is pressed to open the valve so that the negative ion production solution B in the tank 11 can flow out into the storage recess 46.

  On the other hand, the ultrasonic transducer 50 of the ultrasonic generation unit 42 described above is exposed on the bottom surface portion of the atomization recess 47, and the ultrasonic transducer 50 is driven by ultrasonic waves by driving the ultrasonic generation unit 42. On the liquid surface of the negative ion generation solution B staying in the atomization recess 47, and a mist generated by atomization of the negative ion generation solution B (hereinafter also referred to as a preparation mist) appears. It becomes.

  The ultrasonic generation unit 42 is disposed so that the surface of the ultrasonic transducer 50 is 10 to 50 mm from the liquid surface of the negative ion generation solution B, and a driving voltage of 100 to 110 V is used. Ultrasound is transmitted from the ultrasonic transducer 50 having a resonance frequency of 1 to 15 kHz (which promotes hydrolysis) (not atomized). The power consumption at this time is about 35 to 37 W, and the atomization amount per unit time is a maximum of 200 mL / h.

  Here, when the resonance frequency is lower than 1 kHz, the negative ion generation solution B may not be atomized. When the resonance frequency is higher than 15 kHz, a terpene aromatic substance or organic germanium contained in the negative ion generation solution B, etc. This is not preferable because it promotes hydrolysis.

  By configuring the ultrasonic generation unit 42 as described above, the silver ions contained in the negative ion generation solution B and the organic germanium can be diffused at an appropriate concentration.

  Next, the mist blowing unit 30 will be described. Inside the cylindrical body 32, a driving device 34 for rotating the rotating nozzle 31 is disposed.

  The drive device 34 is formed by housing a nozzle rotation motor 35 inside a motor cover 36, and connects a motor shaft 37 of the nozzle rotation motor 35 to a cover shaft 38 of the motor cover 36.

  Further, the cylindrical body 32 incorporates a transmission rod (not shown) having one end connected to the rotating nozzle 31, and the other end of the transmission rod is connected to the cover shaft 38 described above.

  Therefore, by driving the nozzle rotation motor 35, the motor shaft 37 rotates, and this rotational force is transmitted to the rotation nozzle 31 via the cover shaft 38 and the transmission rod, and the rotation nozzle 31 rotates. Will be.

  Next, the structure of the filter 13 will be described with reference to FIG.

  The filter 13 disposed on the bottom surface of the tank 11 is fitted with the filter main body 60 protruding into the hollow interior of the tank 11 and the above-described bottom opening (not shown) drilled in the bottom of the tank 11. And a filter lid 62 that closes the

  The filter main body 60 includes a cylindrical and short outer cylinder 63 and a cylindrical and long inner cylinder 64 disposed inside the hollow of the outer cylinder 63, and the upper portion of the outer cylinder 63 is an upper closing plate. Blocked at 65. However, the upper end portion 68 of the inner cylinder is not closed by the upper closing plate 65 and forms a gap.

  Further, a space formed between the outer cylinder 63 and the inner cylinder 64 is used as a filter medium filling portion 67, and an annular eye plate formed so that a negative ion production solution B can be circulated below the filter medium filling section 67. 66 is fitted.

  Accordingly, the negative ion production solution B in the vicinity of the lower part of the annular dish plate 66 enters the filter medium filling part 67 via the annular dish plate 66, flows into the inner cylinder 64 through the upper end part 68 of the inner cylinder, It is possible to flow out from the opening of the cylinder lower end portion 69.

  Here, as shown in FIG. 4, the filter medium filling portion 67 can store the filter medium. The filter medium is not particularly limited, and may be, for example, activated carbon, fossilized fossil, or a magnetic material such as a magnet that is crushed (in the form of gravel) so that the negative ion production solution B can be circulated.

  And especially preferably, it is good to insert the rock which has the radioactivity of 0.3-0.7 microsievert as a filter medium. Such rocks include, for example, Kitagawa stones produced in Tamagawa Hot Springs, Akita Prefecture, Australia, and the like, and rocks having the same composition. In FIG. 3, for convenience of explanation, the filter medium accommodated in the filter medium filling portion 67 is omitted.

  On the other hand, the filter lid 62 includes a lid body 70 having a substantially double circle shape in plan view, and a water stop valve 71 disposed at a substantially central portion of the lid body 70.

  The lid body 70 is formed by standing an annular inner wall body 73 on the inside of a substantially bowl-shaped outer wall body 72, and the aforementioned water stop valve 71 penetrates through the substantially central portion of the bottom surface of the outer wall body 72. Are arranged.

  Further, the upper end peripheral surface portion of the inner wall body 73 is formed with cutout portions 74 at a plurality of locations (three locations in the present embodiment), and the cutout portions 74 are formed on locking pieces (not shown) on the bottom surface of the tank 11. It engages to close the aforementioned bottom opening.

  As shown in FIGS. 3 and 4, the water stop valve 71 includes a cylindrical valve seat 75 that passes through the substantially central portion of the bottom surface of the outer wall 72, and a valve shaft that passes through the substantially central portion in the radial direction of the valve seat 75. 61, a tension spring 76 (see FIG. 4) as an elastic body wound around the valve shaft 61, and an inverted conical shape fixed to the vicinity of the tip of the valve shaft 61 so as to close the upper opening of the valve seat 75 It is comprised with the valve body 77 formed in this.

  That is, in the normal state, the water stop valve 71 has the valve element 77 in close contact with the upper opening of the valve seat 75 by the tension spring 76, and the negative ion generating solution B in the inner cylinder 64 is transferred to the valve seat 75. The water is prevented from flowing out from the water outlet 78. Hereinafter, this state is referred to as a water stop state.

  Further, the lower end portion of the valve shaft 61 is pressed against the urging force of the tension spring 76 from the water outlet 78, and the valve body 77 is pushed up, so that the negative ion generating solution B in the inner cylinder 64 is combined with the valve body 77. Through the space between the upper end of the valve seat 75, the hollow interior of the valve seat 75 is allowed to flow down and can flow out from the water outlet 78. Hereinafter, this state is referred to as an outflowable state.

  Therefore, as described above, when the solution storage section 10 is placed on the apparatus main body 20 (the receiving tray 41), the pressing protrusion 49 standing on the storage recess 46 presses the valve shaft 61 upward to open the valve. The negative ion production solution B inside the tank 11 can be discharged to the storage recess 46.

  Based on the above-described configuration, a series of flows until the negative ion generation solution B stored in the tank 11 is atomized to become a preparation mist will be described below with reference to FIG.

  The negative ion production solution B stored in advance in the tank 11 does not flow out of the water outlet 78 because the water stop valve 71 of the filter 13 is in a water stop state.

  Here, by placing the solution storage unit 10 on the apparatus main body 20, the valve shaft 61 of the water stop valve 71 comes into contact with the pressing protrusion 49 of the tray 41 and is pressed upward so that the water stop valve 71 flows out. It becomes possible.

  Then, the negative ion production solution B in the tank 11 flows into the filter medium filling unit 67 through the annular plate 66 and rises while contacting the north throwing stone 80.

  The negative ion production solution B that has reached the vicinity of the inner cylinder upper end portion 68 of the filter medium filling portion 67 flows into the inner cylinder 64 through a gap formed between the inner cylinder upper end portion 68 and the upper closing plate 65.

  Here, since the water stop valve 71 is in an outflowable state, the negative ion generation solution B flows down through the valve seat 75 and flows out from the water outlet 78 to the storage recess 46.

  The negative ion production solution B that has flowed into the storage recess 46 flows into the atomization recess 47 through the communication portion 48, gradually increases the water volume, and fills both the storage recess 46 and the atomization recess 47.

  Here, when the apparatus main body 20 is energized, the ultrasonic vibrator 50 exposed on the bottom surface of the atomizing recess 47 generates ultrasonic waves, and a formulation mist is generated on the water surface immediately above.

  The preparation mist is raised inside the cylindrical body 32 by the wind of the blower fan 44 built in the apparatus main body 20, reaches the outlet 33 of the rotating nozzle 31, and is discharged to the outside of the negative ion generator A.

  At this time, by driving the nozzle rotation motor 35, the rotation nozzle 31 rotates, so that the preparation mist is diffused over a wide area around the negative ion generator A.

[Negative ion production solution]
Next, the negative ion production solution B that is a raw material for the preparation mist will be described.

The negative ion production solution B according to this embodiment has the composition shown in Table 1.

  Here, the silver ion solution causes bactericidal and antibacterial properties, and uses a safe material for the human body. The final concentration of silver ions derived from the silver ion solution in the negative ion generation solution B is about 0.3 ppm in this embodiment, but can be adjusted as appropriate within a range of 0.01 to 10 ppm.

  The terpene-containing plant extract serves to stabilize silver ions in the presence of organic germanium as a terpene-based aromatic substance, and also plays a role as a natural sterilizing component.

  In addition, since the terpene-containing plant extract contains a phytoncide component, it can produce a healing effect such as relaxation for the user in the formulation fog atmosphere.

  Organo-germanium is known to have various physiological activities on the human body, and is effective in eliminating pain and numbness, improving depression, and improving blood flow for users in a foggy formulation. Effect, blood pressure adjustment effect, white blood cell strengthening effect, active oxygen removal effect, protein-sugar binding inhibition to prevent diabetic complications, cataract prevention and improvement effect, antigen-antibody reaction It is thought that it has the effect of improving allergic diseases by adjusting the effect, the effect of activating immune cells and suppressing malignant tumors, the side effect of anticancer drugs, the effect of reducing bone loss, the effect of delaying the aging phenomenon, etc. It has been.

  As a feature of the present invention, by preparing silver ion, organic germanium, and terpene to prepare a negative ion generation solution B, alteration of silver ions is prevented and the life of negative ions is extended. It is.

  Moreover, in Table 1, the emulsifier and the alcohol are used to disperse the terpene-containing plant extract in the negative ion production solution B.

[Test 1]
Next, the results of testing the stability of silver ions in the presence of organic germanium with or without terpene-based aromatic substances are shown below.

In this test, the following samples were prepared and tested.
(Chemical solution A) Solution containing silver ions and organic germanium (Chemical solution B) Solution containing silver ions and terpene aromatic substances (Chemical solution C) Solution containing silver ions, organic germanium and terpene aromatic substances ( Chemical solution D) Solution containing silver ions (control)

Table 2 shows the results of storage tests for 12 months for these chemicals A to D.

  As can be seen from Table 2, since the chemical solution A does not contain a terpene aromatic substance, the presence of organic germanium destabilizes silver ions, and the silver ion concentration becomes almost 0 ppm at the 12th month. .

  It can also be seen that the chemical solution B also has a very low value of about 0.1 ppm at 12 months. In particular, it should be noted here that silver ions are not stabilized only by a terpene aromatic substance.

  And the chemical | medical solution C was maintaining the silver ion density | concentration substantially equivalent to the initial concentration also in the 12th month similarly to the chemical | medical solution D which is control.

  From these results, it is considered that silver ions are stabilized in the presence of organic germanium and a terpene aromatic substance.

[Test 2]
Next, the result of having verified about the quantity of the negative ion produced when the negative ion production | generation apparatus A which concerns on this embodiment atomizes the negative ion production | generation solution B or another solution is shown.

Samples used in this test are as follows.
(Sample A) Negative ion production solution B according to this embodiment
(Sample B) Tap water (Sample C) Commercial mineral water (Sample D) Deionized distilled water

Table 3 shows a graph in which each sample is accommodated in the tank 11 and the amount of negative ions in the mist about 5 minutes after the negative ion generator A is moved is measured.

In Table 3, the vertical axis indicates the number of negative ions in 1 cm ³ of the generated mist, and the horizontal axis indicates the type of sample.

As can be seen from Table 3, the formulation mist generated by the negative ion generation solution B (sample A) according to the present embodiment has a large amount of negative ions with a long lifetime supplied from the negative ion generation device A one after another. As a result, as many as 70000 negative ions were detected per 1 cm ³ .

During fog caused by the sample B, 1 cm ³ 6500 per 15,000 per 1 cm ³ in fog in which is generated by the sample C, the fog in which is generated by the sample D 1 cm ³ per 20,000 negative ions detected It was done.

  From these results, it was suggested that the negative ion production solution B according to this embodiment can efficiently generate negative ions.

[Test 3]
Next, in the filter medium filling part 67 formed in the filter 13 of the negative ion generator A, the north throwing stone having a radioactivity of 0.3 to 0.7 microsievert is accommodated, and the negative ion generated when the negative ion generation solution B is atomized. The number of ions was examined.

Table 4 shows a graph in which the negative ion production solution B is accommodated in the tank 11 and the negative ion production device A is moved with or without the north stone thrown, and the amount of negative ions in the preparation mist after about 5 minutes is measured.

In Table 4, the vertical axis indicates the number of negative ions in 1 cm ³ of the generated fog, and the horizontal axis indicates the presence or absence of north stone.

As can be seen from Table 4, as many as 86,200 negative ions per 1 cm ³ were detected in the formulation mist generated by containing Kitaishi stone in the filter medium filling portion 67.

On the other hand, the formulation mist generated without containing the north throwing stone in the filter medium filling portion 67 was 71500 per 1 cm ³ , which was less than the preparation mist generated by containing the north throwing stone.

  From these results, it was suggested that negative ions can be generated more efficiently by filling the filter medium filling portion 67 with rock having radioactivity.

  As described above, according to the negative ion generation solution B according to the present invention, since the aqueous solvent contains silver ions, organic germanium, and a terpene aromatic substance, it is relatively long in the air. It is possible to generate negative ions having a lifetime and to allow silver ions to stably exist in a liquid before spraying in which silver ions and organic germanium coexist.

  Further, in the negative ion generation apparatus A according to the present embodiment, in the negative ion generation apparatus capable of generating negative ions by spraying a liquid negative ion generation solution, the negative ion generation solution contains silver as an aqueous solvent. Because it contains ions, organic germanium, and terpene-based aromatic substances, it can generate negative ions with a relatively long lifetime in air, and before spraying, where silver ions and organic germanium coexist. Silver ions can be stably present in the liquid.

  Moreover, since the output of the ultrasonic generation unit 42 of the negative ion generator A is set to 25 to 40 W, it is possible to disperse both in the mist while preventing the silver ions and organic germanium from collapsing due to ultrasonic vibration. Can be made.

  In addition, the filter medium filling portion 67 can be further improved in negative ion generation efficiency by filling with rocks having a radioactivity of 0.3 to 0.7 microsievert such as north throwing stone, and it is weak against fog. It is possible to cause a physiological stimulus (so-called hormesis effect) that exhibits a good action on a living body such as a human by imparting a sufficient radioactivity.

  Further, as an example, by atomizing the negative ion production solution B in the room with the negative ion production apparatus A, it is possible to create an atmosphere of a radioactive hot spring such as Tamagawa Onsen while purifying the room. It can be done.

  In addition, it goes without saying that the silver ions and the organic germanium contained in the negative ion generation solution B can enjoy the physiological activities individually possessed.

  Finally, the description of each embodiment described above is an example of the present invention, and the present invention is not limited to the above-described embodiment. For this reason, it is a matter of course that various modifications other than the above-described embodiments can be made according to the design and the like as long as they do not depart from the technical idea according to the present invention.

  For example, the capacity of the tank 11 disposed in the negative ion generation apparatus A according to the present embodiment may be reduced, or the apparatus main body 20 may be reduced in size so as to have a compact shape.

  By making the negative ion generation apparatus A into a compact shape, the occupied area can be reduced, and it can be easily arranged in a place desired by the user, thereby further increasing the use opportunity.

It is explanatory drawing which showed the external appearance of the negative ion production | generation apparatus A which concerns on this embodiment. It is a disassembled perspective view of the negative ion production | generation apparatus A which concerns on this embodiment. It is decomposition | disassembly explanatory drawing of the filter arrange | positioned at the negative ion production | generation apparatus A which concerns on this embodiment. It is sectional explanatory drawing of the negative ion production | generation apparatus A which concerns on this embodiment.

Explanation of symbols

A Negative ion generator B Negative ion generator
11 tanks
13 Filter
42 Ultrasonic generator
50 ultrasonic transducer
67 Filter material filling part
80 North Stone

Claims (4)

In a liquid negative ion generating solution that can generate negative ions by spraying with a spray device,
A negative ion generating solution characterized by containing silver ions, organic germanium, and a terpene aromatic substance in an aqueous solvent. In the negative ion generator capable of generating negative ions by spraying a liquid negative ion generating solution,
The negative ion generation solution contains silver ions, organic germanium, and a terpene aromatic substance in an aqueous solvent. A tank for storing the negative ion generating solution;
A filter that is disposed at the outlet of the tank and allows water to pass through while filtering the negative ion production solution;
An ultrasonic generation unit that atomizes the negative ion generation solution that has flowed out through the filter,
The negative ion generation apparatus according to claim 2, wherein the ultrasonic wave generation unit has an output of 25 to 40W.   4. The negative ion generation according to claim 3, wherein the filter includes a filter material filling portion, and the filter material filling portion is filled with a rock having a radioactivity of 0.3 to 0.7 microsievert. apparatus.

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