JP2016182593A - Negative ion water generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a negative ion water generator improving the dissolution rate of negative ions to water and improving the negative ion concentration of the negative ion water.SOLUTION: Provided is a negative ion water generator 1 comprising: a main body 11; a negative ion generator 12; an ultrasonic generator 13; a power source feed module 14; and a container C. The negative ion generator is coupled to the main body and is connected with a tube 121 and an air pump 122, respectively, in the tube, a negative ion release port 121a is formed at the edge separated from the negative ion generator, the ultrasonic generator is coupled to the main body and is connected with a vibrator 131 with a rod 132, the power source feed module is coupled to the main body and is electrically connected with the negative ion generator, the air pump and the ultrasonic generator, respectively, the container has an opening C1, and the tube and the rod elongate to the inside of the container than the opening in such a manner that the negative ion release port and the vibrator of the ultrasonic generator are formed at the inside of the container.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a negative ion water generator, and more particularly to a negative ion water generator that is useful for reducing water clusters and further dissolving negative ions.

The conventional negative ion water generator 9 shown in FIG. 12 has a tank 91 and a negative ion generator 92. The negative ion generator 92 is fixed to the outside of the tank 91, and the negative ion generator. 92 has a negative ion discharge port 921, and this negative ion discharge port 921 is installed toward the through hole 911 provided in the outer wall of the tank 91.
As a result, the negative ion generator 92 continues to release negative ions from the negative ion discharge port 921, and the negative ions enter the tank 91 through the through-hole 911 to be dissolved in the water. Is formed in negative ion water.
For a conventional negative ion water generator 9, see, for example, Patent Document 1.

Taiwan M266428 Notification

However, since the negative ions released from the negative ion discharge port 921 enter the tank 91 through the through-hole 911 and contact only the liquid level of the water body W, the dissolution rate of the negative ions in the water body W is delayed, and After a certain amount of negative ions are dissolved in the water body W, the negative ions have a high concentration at a location near the liquid surface of the water body W, and the water body W cannot dissolve further negative ions from the liquid surface.
Thereby, when producing negative ion water using the negative ion water generator 9, the dissolution rate of negative ions in water may be too slow, which may reduce the practicality of the negative ion water generator 9.

Furthermore, due to the influence of hydrogen bonding, the molecular structure of water generates a pulling force between one water molecule and neighboring water molecules, and this force has a cohesive force on the water body formed by the collection of water molecules. In addition, since a large amount of water molecules are contained in the water body, the water molecules in the water body attract each other and form a large number of water clusters due to the influence of hydrogen bonds.
In general, a water cluster of tap water is composed of approximately 14 or more water molecules.
In the water body W, when there is no influence of external force, the number of water molecules contained in the water cluster formed naturally by the water molecule is large, and the volume of the water cluster in the water body W is increased. The ratio of negative ions which are difficult to adhere and have been successfully dissolved in the water body W is reduced.
Therefore, the negative ion water produced by the conventional negative ion water generator 9 has a low negative ion concentration.

  In view of this, when producing negative ion water with the conventional negative ion water generator 9 such as “the dissolution rate of negative ion water is too slow” and “the negative ion concentration of the produced negative ion water is low”. There is a need for an improved negative ion water generator that can solve these problems.

  In the present invention, a negative ion generator is coupled to a main body, the negative ion generator connects a tube, and the tube has a negative ion discharge port formed at an end away from the negative ion generator, An object of the present invention is to provide a negative ion water generator that extends the inside of a container and forms a negative ion discharge port inside the container to improve the dissolution rate of negative ions in the water body.

  In the present invention, an ultrasonic generator is coupled to a main body, and the ultrasonic generator is connected to a vibrating body from a rod, the rod extends into the container, and the vibrating body is formed inside the container. It is another object of the present invention to provide a negative ion water generator having an effect of improving the negative ion concentration of negative ion water produced in the negative ion water generator.

  In order to achieve the above object, technical means of the present invention are as follows.

  A negative ion water generator including a main body, a negative ion generator, an ultrasonic generator, a power supply module, and a container, wherein the negative ion generator is coupled to the main body, and the negative ion generator is A tube and an air pump are connected to each other, the tube is formed with a negative ion emission port at an end away from the negative ion generator, the ultrasonic generator is coupled to the body, and the ultrasonic generator is a rod. The vibrating body is coupled, the power supply module is coupled to the main body, the power supply module is electrically connected to the negative ion generator, the air pump and the ultrasonic generator, respectively, and the container has an opening. A negative ion discharge port of the negative ion generator and a vibrating body of the ultrasonic generator are formed inside the container. In the tube and rod, negative ion water generator, characterized by stretching from the opening to the interior of the container.

  In the negative ion water generator of the present invention, the main body includes a stand and a pedestal, the stand is coupled to the pedestal, and the stand extends in a longitudinal direction away from the pedestal, and the negative ion generator And an ultrasonic generator are each coupled to the stand.

  In the negative ion water generator of the present invention, the tube of the negative ion generator protrudes outside the stand of the main body and extends to the pedestal along the vertical direction, and the rod of the ultrasonic generator is also Projects to the outside of the stand of the main body and extends to the pedestal along the vertical direction.

  In the negative ion water generator of the present invention, the container is installed adjacent to the base of the main body.

  The negative ion water generator of the present invention further includes a magnetizer, the magnetizer is a permanent magnet manufactured by a hard magnetic material, and the magnetizer is installed adjacent to the base of the main body, and , Facing the tube and rod along the longitudinal direction.

  The negative ion water generator of the present invention further includes a magnetizer, and the magnetizer includes an electromagnetic coil. The magnetizer is coupled to the main body and is electrically connected to the power supply module.

  In the negative ion water generator of the present invention, the pedestal of the main body has a mounting surface, and the mounting surface faces the tube of the negative ion generator and the rod of the ultrasonic generator along the vertical direction, A magnetizer is installed at a position adjacent to the mounting surface of the pedestal.

  In the negative ion water generator of the present invention, the container is installed on the mounting surface of the pedestal.

  In the negative ion water generator of the present invention, the power supply module includes a power line, and the power line is electrically connected to a power source outside the negative ion water generator.

  In the negative ion water generator of the present invention, the container is connected to a water discharge pipe, an end of the water discharge pipe communicates with a water discharge port, and the water discharge pipe further includes a magnetizer, It has a permanent magnet, the said permanent magnet is installed in the said water discharge pipe, and magnetic field strength is 3000-5000 Gs.

  In the negative ion water generator of the present invention, the permanent magnet has a magnetic field strength of 4000 ± 10% Gs.

  In the negative ion water generator of the present invention, the permanent magnet is installed on the outer periphery of the water discharge pipe.

  In the negative ion water generator of the present invention, the magnetic pole surface of the permanent magnet is bonded and fixed to the outer peripheral wall of the water discharge pipe.

  In the negative ion water generator of the present invention, a coupling surface is installed on the outer peripheral wall of the water discharge pipe, and the magnetic pole surface of the permanent magnet is bonded to the coupling surface.

  In the negative ion water generator of the present invention, the magnetizer has a magnetic field blocking member, and the magnetic field blocking member is a permanent magnet so that one magnetic pole surface of the permanent magnet is exposed and bonded to the water discharge pipe. Cover.

  In the negative ion water generator of the present invention, the magnetizer has a cover, and the cover covers the magnetic field shielding member.

  The negative ion water generator of this invention has a rust prevention layer between the said magnetic field interruption | blocking member and a cover.

  In the negative ion water generator of the present invention, the rust prevention layer is formed on the outer surface of the magnetic field shielding member or the inner surface of the cover.

  In the negative ion water generator of the present invention, the magnetizer has at least one fixing member, and the fixing member abuts the cover so that the permanent magnet, the magnetic field shielding member, and the cover are tightly bound to the water discharge pipe. Touched.

  In the negative ion water generator of the present invention, the magnetizer further has another permanent magnet, and the two permanent magnets are installed along the outer peripheral wall of the water discharge pipe.

  In the negative ion water generator of the present invention, the two permanent magnets are installed opposite to each other with different magnetic poles in the radial direction of the water discharge pipe.

  In the negative ion water generator of the present invention, the surface to be bonded to the water discharge pipe of the permanent magnet is a curved surface.

  The negative ion water generator of the present invention improves the dissolution rate of negative ions in the water body by forming the negative ion discharge port of the negative ion generator inside the container. By forming it inside the container, the water body is vibrated, and the negative ion concentration of negative ion water produced in the negative ion water generator is improved.

1 is an external schematic perspective view of a first embodiment of the present invention. The external appearance schematic perspective drawing of the 2nd Example of this invention. The external appearance schematic perspective view of the 3rd Example of this invention. The external appearance schematic perspective view of 4th Example of this invention. The schematic enlarged view of the water discharge pipe and magnetizer of the container in 4th Example of this invention. The schematic structural solid view of 1st embodiment of the magnetizer in the 4th Example of this invention. The schematic sectional drawing of 1st embodiment of the magnetizer in the 4th Example of this invention. The schematic sectional drawing of 2nd embodiment of the magnetizer in the 4th Example of this invention. The schematic sectional drawing of 3rd embodiment of the magnetizer in the 4th Example of this invention. The schematic sectional drawing from another viewing angle of 3rd embodiment of the magnetizer in the 4th example of the present invention. The nuclear magnetic resonance measurement result figure of the water cluster which has the water molecule which carried out the negative ionization obtained from 4th Example of this invention. Sectional drawing of the structure of the conventional negative ion generator.

  An embodiment of the present invention will be described below with reference to the drawings.

“Negative ion water” described in the entire specification of the present invention refers to water containing negative ionized water molecules.
More specifically, negatively charged hydroxide ions (OH ⁻ ) are attached to water molecules, and water molecules are formed into negatively ionized water molecules (H ₂ O ₃ ⁻ ).
The negative ion concentration described in the entire specification of the present invention refers to the concentration of negatively ionized water molecules contained in the water body and can be understood by those skilled in the art.

A negative ion generator 1 according to the first embodiment of the present invention shown in FIG. 1 includes a main body 11, a negative ion generator 12, an ultrasonic generator 13, and a power supply module 14.
The negative ion generator 12, the ultrasonic generator 13, and the power supply module 14 can be coupled to the main body 11, respectively.

More specifically, the main body 11 includes a stand 111 and a pedestal 112, and the stand 111 is coupled to the pedestal 112.
The pedestal 112 is used to connect to the surface of a table or other object, and the stand 111 can extend along the longitudinal direction X away from the pedestal 112.
The negative ion generator 12 and the ultrasonic generator 13 can be coupled to a stand 111, respectively, so that when the pedestal 112 is coupled to a table surface or other object surface, the negative ion generation is performed. The vessel 12 and the ultrasonic generator 13 can be spaced apart from a table or other object in the longitudinal direction X.

The negative ion generator 12 is connected to a pipe 121 and an air pump 122, and a negative ion discharge port 121 a is formed at the end of the pipe 121 away from the negative ion generator 12.
The tube 121 protrudes outside the stand 111 of the main body 11 and extends to the pedestal 112 along the vertical direction X.
The air pump 122 may be a known micro air pump, and the negative ion generator 12 and the air pump 122 are electrically connected to the power supply module 14, respectively, so that the negative ion generator 12 and the air pump 122 are connected. The electricity necessary for the operation of the can be obtained.
Thereby, the air pump 122 drives air into the negative ion generator 12, and the negative ion generator 12 converts a low voltage into a negative DC high voltage by a known boosting element such as a pulse current or a vibrator. The air inside is ionized to form negative ions.
Since the air pump 122 continues to drive air into the negative ion generator 12, the air passing through the negative ion generator 12 is discharged from the negative ion discharge port 121a through the tube 121 together with the negative ions.
Since the operation principle of the negative ion generator 12 can be understood and implemented by those skilled in the art, detailed operation methods relating to the negative ion generator 12 and the air pump 122 are omitted.

The ultrasonic generator 13 connects a vibrating body 131. More specifically, the ultrasonic generator 13 connects the vibrating body 131 by a rod 132, and the rod 132 is connected to the outside of the stand 111 of the main body 11. It protrudes and extends to the pedestal 112 along the longitudinal direction X.
The ultrasonic generator 13 can obtain electricity necessary for the operation of the ultrasonic generator 13 by being electrically connected to the power supply module 14.
The ultrasonic generator 13 is used to generate a vibration wave having a frequency exceeding 20 kHz. The vibration wave is transmitted to the vibration body 131 by the rod 132, and the vibration body 131 is vibrated.

The power supply module 14 may be a power conversion device (for example, a transformer), whereby the power supply module 14 is connected to a power source external to the negative ion water generator 1 (for example, a local power source) via a power line 141. ) And the power supply module 14 may perform processing such as transformation and AC / DC conversion on the power imported from the power line 141, thereby Electricity necessary for the operation of the generator 12, the air pump 122 or the ultrasonic generator 13 is supplied.
However, the power supply module 14 may be an independent power supply device (for example, a battery set), so that the power supply module 14 is directly connected to the negative ion generator 12, the air pump 122, or the It can be easily estimated by those skilled in the art that electricity necessary for the operation of the sound wave generator 13 can be supplied, and that it is not necessary to be electrically connected to an external power source of the negative ion water generator 1.

Further referring to FIG. 1, the negative ion water generator 1 according to the first embodiment of the present invention may be installed adjacent to the pedestal 112 of the main body 11 when actually used. The container C may have an opening C 1, and the opening C 1 may face the tube 121 of the negative ion generator 12 and the rod 132 of the ultrasonic generator 13.
As a result, the tube 121 and the rod 132 extend into the container C from the opening C1, and the negative ion discharge port 121a of the negative ion generator 12 and the vibrator 131 of the ultrasonic generator 13 are connected to the container. It is formed inside C.

The inside of the container C accommodates the water body W, whereby the negative ion discharge port 121a and the vibrating body 131 are formed in the water body W.
In the negative ion water generator 1 according to the first embodiment, after starting, the negative ion generator 12 generates negative ions, and discharges negative ions from the negative ion discharge port 121a through the tube 121. The negative ions are negative. It enters the water body W from the ion discharge port 121a.
At the same time, the ultrasonic generator 13 generates a vibration wave, transmits the vibration wave to the vibration body 131 by the rod 132, vibrates the vibration body 131, and further vibrates the water body W.
As a result, the negative ions are effectively dissolved in the water body W, adhere to the water molecules contained in the water body W, form water molecules contained in the water body W into negatively ionized water molecules, and further, the water body W becomes negative. Form in ionic water.

It should be noted that since the negative ion discharge port 121a of the negative ion generator 12 is formed inside the container C, the negative ion discharge port 121a is formed in the water body W, and the negative ion generator 12 is formed. Is connected to an air pump 122, and this air pump 122 continues to send air to the negative ion generator 12 to forcibly release negative ions from the negative ion discharge port 121a, so that negative ions are discharged from the negative ion discharge port 121a. After being released, the water body W directly enters the water body W and can sufficiently contact water molecules contained in the water body W.
In the conventional negative ion generator 9, the negative ions released from the negative ion discharge port 921 are in contact only with the liquid surface of the water body W, and the contact area between the negative ions and the water body W is small. The negative ion water generator 1 according to the first embodiment directly enters the water body W after the negative ions are released from the negative ion discharge port 121a, and forms a larger contact area between the negative ions and the water body W. Therefore, it has the effect of improving the dissolution rate of negative ions in the water body W.

Further, when negative ion water is produced using the negative ion water generator 1 according to the first embodiment of the present invention, after some negative ions are dissolved in the water body W like the conventional negative ion water generator 9. The water W will not be able to dissolve further negative ions from the liquid surface due to the influence of the high concentration of negative ions near the liquid surface of the water W.
On the other hand, in the present embodiment, since negative ions enter the water body W directly after being discharged from the negative ion discharge port 121a, the negative ions are uniformly dissolved in the water body W, and the negatively ionized water molecules are converted into the water body. Since it is uniformly dispersed in W, the dissolution rate of negative ions in the water body W is less likely to decrease as the concentration of negative ions in the water body W increases.

Further, it is known that the ultrasonic generator 13 can generate a vibration wave having a frequency exceeding 20 kHz, and the vibration wave generated from the ultrasonic generator 13 is transmitted to the vibration body 131 to vibrate the water body W. In this case, hydrogen bonds in the water molecule structure can be broken, the attractive force between adjacent water molecules can be reduced, and the number of water molecules in the water cluster contained in the water body W can be effectively reduced.
As a result, the negative ion water generator 1 according to the first embodiment of the present invention reduces the volume of the water cluster contained in the water body W by installing the ultrasonic generator 13, and the negative ions become water molecules. The degree of difficulty of adhering can be reduced, and further, the ratio of negative ions successfully dissolved in the water body W is improved, and the negative ion concentration of negative ion water produced in the negative ion water generator 1 is improved. Surely have.

The negative ion generator 1 according to the second embodiment of the present invention shown in FIG. 2 further includes a magnetizer 15 as a different point from the first embodiment, and the magnetizer 15 is made of a hard magnetic material. The magnetizer 15 is installed adjacent to the pedestal 112 of the main body 11.
The magnetizer 15 may be opposed to the tube 121 and the rod 132 along the longitudinal direction X. By installing the container C on the upper surface of the magnetizer 15, the tube 121 and the rod 132 are opened. It can be extended from C1 into the container C.

In the negative ion generator 1 according to the second embodiment of the present invention, since the magnetizer 15 is a permanent magnet by installing the magnetizer 15 at a position adjacent to the mounting surface 112a of the pedestal 112, the magnetizer 15 is a static magnet. The magnetic field can continue to be generated, and the static magnetic field can cover the container C installed on the upper surface of the magnetizer 15, thereby performing the magnetization process on the water body W of the container C.
The water cluster contained in the water body W undergoes a magnetization reaction when affected by the magnetic field generated by the magnetizer 15 to reduce the number of water molecules in the water cluster, and further, the water cluster contained in the water body W Reduce the volume.
Accordingly, the negative ion generator 1 according to the second embodiment of the present invention can reduce the volume of the water cluster of the water body W by using the ultrasonic generator 13 and the magnetizer 15 at the same time. The effect of improving the negative ion concentration of the negative ion water produced in the generator 1 is further enhanced.

Further, the negative ion generator 1 according to the third embodiment of the present invention shown in FIG. 3 similarly includes a magnetizer 15 ′, and as a difference from the second embodiment, the magnetizer 15 ′ includes an electromagnetic coil. And coupled to the pedestal 112 and electrically connected to the power supply module.
More specifically, in this embodiment, the pedestal 112 of the main body 11 has a mounting surface 112a, and the mounting surface 112a extends along the longitudinal direction X with the tube 121 of the negative ion generator 12 and the ultrasonic generator. It is preferable that the container C is placed on the mounting surface 112a of the pedestal 112, and the container C is coupled to the mounting surface 112a on the side away from the opening C1. Thus, the tube 121 and the rod 132 extend from the opening C1 to the inside of the container C.
The magnetizer 15 ′ may be installed at a position adjacent to the mounting surface 112 a of the pedestal 112.
The magnetizer 15 ′ can be electrically connected to the power supply module 14, thereby obtaining electricity necessary for the operation of the magnetizer 15 ′.

In the water cluster negative ion generator 1 according to the third embodiment of the present invention, by installing a magnetizer 15 ′ made of an electromagnetic coil at a position adjacent to the mounting surface 112a in the pedestal 112, the magnetizer 15 ′ An alternating magnetic field can be generated using an alternating current, and this alternating magnetic field can cover the container C installed on the mounting surface 112a through the pedestal 112, and magnetizes the water body W of the container C.
The water cluster contained in the water body W generates a magnetization reaction when affected by the alternating magnetic field generated in the magnetizer 15 ′, and performs a magnetization process on the water body W of the container C using a static magnetic field. Compared with the embodiment, the magnetizer 15 ′ in this embodiment generates an alternating magnetic field to magnetize the water body W of the container C, and further improves the effect of reducing the volume of water clusters contained in the water body W. The efficiency of dissolving negative ions in the water body W is improved.

The negative ion generator 1 according to the fourth embodiment of the present invention shown in FIGS. 4 and 5 also includes a magnetizer 15. The difference from the second and third embodiments is that the magnetizer 15 includes at least The permanent magnet 151 is a permanent magnet made of a hard magnetic material, and the container C is connected to the water discharge pipe C2.
The end of the water discharge pipe C2 may communicate with the water discharge port C3, whereby the water body W accommodated in the container C flows out through the water discharge pipe C2 and the water discharge port C3 and is used by the user.
The permanent magnet 151 is installed in the water discharge pipe C2, magnetizes the water body W passing through the water discharge pipe C2 by the magnetic force of the permanent magnet 151, and reduces the water cluster.
The magnetic field strength of the permanent magnet 151 is about 3000 to 5000 Gs, preferably 4000 ± 10% Gs.
In addition, the said permanent magnet 151 may be installed in the outer periphery of the water discharge pipe C2, or may be fixed inside the water discharge pipe C2.
When the permanent magnet 151 is installed on the outer periphery of the water discharge pipe C2, the closer the permanent magnet 151 is to the outer periphery of the water discharge pipe C2, the better the effect of magnetizing distilled water passing through the water discharge pipe C2. The vessel 15 can be fixed to the outer peripheral wall of the water discharge pipe C2 with the magnetic pole surface (N pole or S pole) of the permanent magnet 151.

In addition to the basic function of magnetizing the water body W from the permanent magnet 151 as described above, the magnetizer 15 is used as necessary so as to improve the safety of use and assembly convenience of the magnetizer 15. Parts may be increased.
Several embodiments of the magnetizer 15 are described as follows.

  In the first embodiment of the magnetizer 15 shown in FIGS. 6 and 7, the permanent magnet 151 of the magnetizer 15 generally forms a cube, in order to improve the coupling stability between the permanent magnet 151 and the water discharge pipe C2. In addition, a coupling surface C21 may be provided on the outer peripheral wall of the water discharge pipe C2, whereby the magnetic pole surface of the permanent magnet 151 is bonded to the coupling surface C21.

In the present invention, since the permanent magnet 151 having a considerably high magnetic field strength is used, the magnetizer 15 preferably further includes a magnetic field blocking member 152. One magnetic pole surface of the permanent magnet 151 is exposed and the water discharge pipe C2 is exposed. The magnetic field blocking member 152 covers the permanent magnet 151 so as to be bonded to each other, thereby preventing leakage of magnetic force of the permanent magnet 151, and the magnetic substance is attracted to the permanent magnet 151, so that the outside of the negative ion water generator 1 is The negative ion water generator 1 is difficult to peel off from the outside of the negative ion water generator 1, and consequently affects the life risk of a user who is implanted with an implantable medical device such as a cardiac pacemaker. To prevent that.
The magnetic field shielding member 152 may be made of low carbon steel, stainless steel, or other metal material having a magnetic field shielding effect.

Further, the magnetizer 15 can further be provided with a cover 153. The cover 153 covers the magnetic field shielding member 152, has a buffering capacity, protects the permanent magnet 151 and the magnetic field shielding member 152, and has an external force. It becomes difficult to be damaged when receiving.
In this embodiment, the magnetic field blocking member 152 and the cover 153 can be engaged with each other.
Further, it is preferable that a rust prevention layer R is provided between the magnetic field shielding member 152 and the cover 153, and moisture and oxygen are isolated by the rust prevention layer R so that the permanent magnet 151 and the magnetic field shielding member 152 are changed over time. Prevents rusting.
In order to simplify the structure and improve the assembly convenience, rust prevention layer R is selected by selecting varnish or electroplating (for example, nickel plating) on the outer surface of magnetic field blocking member 152 or the inner surface of cover 153. Can be formed.

Means for coupling and fixing the permanent magnet 151, the magnetic field blocking member 152, and the cover 153 of the magnetizer 15 to the water discharge pipe C2 is not limited. For example, the permanent magnet 151, the magnetic field blocking member 152, and the cover 153 are adhered by adhesion. It can be bonded and fixed to the outer peripheral wall of the water discharge pipe C2.
Alternatively, the magnetizer 15 may further be provided with at least one fixing member 154, which abuts the fixing member 154 against the cover 153, and the fixing member 154 causes the permanent magnet 151, the magnetic field blocking member 152, and the cover 153 to be in contact with each other. Is firmly bound to the water discharge pipe C2, thereby preventing the permanent magnet 151, the magnetic field blocking member 152 and the cover 153 from being unwound from the water discharge pipe C2.

In the second embodiment of the magnetizer 15 shown in FIG. 8, the device 15 includes two sets of permanent magnets 151, a magnetic field shielding member 152, and a cover 153, and the two permanent magnets 151 are the outer peripheral wall of the water discharge pipe C2. For example, the two permanent magnets 151 may be installed relative to each other in the radial direction of the water discharge pipe C2.
Since each set of permanent magnet 151, magnetic field blocking member 152, and cover 153 in this embodiment is the same as that described in the first embodiment, description thereof is omitted here.
Thereby, the water body W which lets the water discharge pipe C2 pass simultaneously by the magnetic force of the two permanent magnets 151 can be magnetized, and the effect of reducing the water cluster can be improved.
It should be noted that when the two permanent magnets 151 are installed relative to each other in the radial direction of the water discharge pipe C2, the two permanent magnets 151 should be opposed to each other with different magnetic poles. Improve the magnetizing effect.
In addition, the magnetizer 15 in this embodiment further includes at least one fixing member 154, and the two fixing magnets 151, the magnetic field blocking member 152, and the cover are formed by firmly fixing the fixing member 154 to the outer periphery of the two covers 153. Ensure that 153 is stably coupled to the water discharge pipe C2.

In the third embodiment of the magnetizer 15 shown in FIGS. 9 and 10, the device 15 includes two sets of permanent magnets 151, a magnetic field shielding member 152 and a cover 153, and differs from the second embodiment in that In the present embodiment, the surface of each magnet 151 to be bonded to the water discharge pipe C2 is a curved surface, thereby increasing the area where the two permanent magnets 151 cover the outer peripheral wall of the water discharge pipe C2 and magnetizing the water body W. To further improve.
In the form of the permanent magnet 151, the magnetic field blocking member 152 and the cover 153 cannot be directly covered along the radial direction of the water discharge pipe C2, so that the magnetic field blocking member 152 and the cover 153 of the present embodiment have openings on the side surfaces. Thus, the magnetic field blocking member 152 and the cover 153 can be directly covered along the axial direction of the water discharge pipe C2, and the opening can be sealed later.
Or the permanent magnet 151 can also be covered on the outer peripheral wall of the water discharge pipe C2 by making the magnetic field interruption | blocking member 152 cyclic | annular.

  In particular, when the magnetizer 15 has two or two or more permanent magnets 151, the plurality of permanent magnets 151 may not be installed in the radial direction of the water discharge pipe C2, and the axis of the water discharge pipe C2 It can be installed at intervals along the outer peripheral wall in the direction, which is suitable for an embodiment in which the water body W is magnetized by dividing the section and the water discharge pipe C2 has a plurality of curves.

Regarding the measurement of water clusters, a method is known in which the number of water molecules in a water cluster is known by measuring the vibration frequency of water using nuclear magnetic resonance (abbreviated as NMR).
That is, the higher the vibration frequency, the greater the number of water molecules contained and the lower the quality of the water.
On the other hand, the lower the vibration frequency, the smaller the number of water molecules contained and the higher the quality of water.
In general, if a water cluster contains 5 to 9 water molecules, it is called “microcluster water”, and its vibration frequency is lower than 90 Hz.
Microcluster water has many advantages, which can be understood by those skilled in the art. For example, microcluster water is osmotic to cellular tissues and has dense protein gaps (“ It is also referred to as “water passage”, and the width of about 2 μm) can be easily taken in and out, so that it is easily absorbed by the human body and has an effect of promoting metabolism.
In addition, since the microcluster water is generally weakly basic, it can suppress acidification of the human body and is useful for maintaining health.

Due to the above structure, when the negative ion generator 1 according to the fourth embodiment of the present invention shown in FIG. 4 is operated, the negative ion generator 12 generates negative ions and passes through the tube 121 from the negative ion discharge port 121a. By releasing the ions, negative ions enter the water body W from the negative ion discharge port 121a, and the negative ions can be effectively dissolved in the water body W, adhere to the water molecules of the water body W, and the water body W The water molecules are formed into negatively ionized water molecules, and the water body W is formed into negative ion water.
At the same time, when the user collects the water body W from the water outlet C3, the water body W is magnetized by the permanent magnet 151 of the magnetizer 15 through the water discharge tube C2 to reduce its water cluster, so that the water body W is negatively ionized. A water cluster having water molecules is formed and flows out from the water outlet C3 and used for drinking and other purposes.

Referring to FIG. 11, the negative ion water generator 1 according to the fourth embodiment can reduce the water cluster of the water body W by the magnetizer 15, thereby generating a water cluster having negative ionized water molecules. In order to verify that the water body W collected from the spout C3 using a nuclear magnetic resonance apparatus manufactured by Bruker Corporation of Germany, an absorption peak appeared at a chemical shift of 3.18 ppm. The vibration frequency (the frequency of the absorption peak) is estimated to be 68.17 Hz, and the vibration frequency is smaller than 90 Hz, and therefore meets the definition of “microcluster water”.
Therefore, the negative ion water generator 1 according to the fourth embodiment can reliably generate a water cluster having negatively ionized water molecules.
Thereby, even if the water body W is taken from a water source having a large water cluster (for example, tap water), the user can use the negative ion water generator 1 according to the fourth embodiment to have the water cluster having negatively ionized water molecules. It can be conveniently acquired and is beneficial to maintaining health.

  With the above-described structure, the main features of the negative ion water generator 1 according to the first, second, third and fourth embodiments of the present invention are as follows.

The negative ion generator 12 and the ultrasonic generator 13 are connected to the main body 11, and the negative ion generator 12 is connected to a tube 121, which has a negative ion discharge port 121 a at an end away from the negative ion generator 12. The ultrasonic generator 13 is formed by connecting the vibrating body 131 by a rod 132.
The negative ion generator 12 generates negative ions, emits negative ions from the negative ion discharge port 121 a, generates a vibration wave of the ultrasonic generator 13, and transmits the vibration wave to the vibrating body 131.

As a result, when the container C is installed adjacent to the pedestal 112 of the main body 11, the tube 121 and the rod 132 extend into the container C from the opening C 1 of the container C and the negative ion generator 12 releases the negative ions. The exit 121a and the vibrator 131 of the ultrasonic generator 13 are formed inside the container C.
As can be seen from the above, after the negative ions are released from the negative ion discharge port 121a, they directly enter the water body W and are discharged from the negative ion discharge port 921 of the conventional negative ion water generator 9. However, the negative ion water generator 1 according to the first embodiment of the present invention has negative ions that are only in contact with the liquid surface of the water body W and the contact area between the negative ions and the water body W is small. Since it directly enters the water body W after being discharged from the discharge port 121a and forms a larger contact area between the negative ions and the water body W, it has the effect of improving the dissolution rate of the negative ions in the water body W.

  Furthermore, since the vibrating body 131 is formed in the water body W, when the vibration wave generated from the ultrasonic generator 13 is transmitted to the vibrating body 131, the vibrating body 131 vibrates to vibrate the water body W, and the water body The volume of the water cluster contained in W can be reduced, and the negative ion concentration produced in the negative ion water generator 1 can be improved by improving the ratio of negative ions successfully dissolved in the water body W. It has the effect of improving.

On the other hand, the negative ion water generator 1 according to the second and third embodiments of the present invention further includes magnetizers 15 and 15 ', which generate a magnetic field, and The water body W of the container C is magnetized by using a magnetic field, the volume of the water cluster contained in the water body W can be reduced, and the negative ion concentration of the negative ion water produced in the negative ion water generator 1 is improved. To make the effect to be more remarkable.
Alternatively, in the negative ion water generator 1 according to the fourth embodiment of the present invention, the magnetizer 15 is a permanent magnet 151 having a magnetic field strength of about 3000 to 5000 Gs, and the water discharge pipe C2 is generated by the magnetic force of the permanent magnet 151. The water body W passing through is magnetized, the water cluster is reduced, and a water cluster having negatively ionized water molecules can be generated.

  As described above, the negative ion water generator 1 of the present invention reliably reaches the effect of improving the dissolution rate of negative ions in water and the effect of improving the negative ion concentration of the manufactured negative ion water.

The present invention may be implemented in other ways without departing from the spirit and essential characteristics thereof.
Accordingly, the preferred embodiments described herein are exemplary and are not intended as limitations on the scope of the invention.

DESCRIPTION OF SYMBOLS 1 Negative ion water generator 11 Main body 111 Stand 112 Base 112a Mounting surface 12 Negative ion generator 121 Pipe 121a Negative ion discharge port 122 Air pump 13 Ultrasonic generator 131 Vibrating body 132 Rod 14 Power supply module 141 Power line 15 Magnetizer 15 'Magnetizer 151 Permanent magnet 152 Magnetic field blocking member 153 Cover 154 Fixed member X Longitudinal direction C Container C1 Opening C2 Water discharge pipe C21 Bonding surface C3 Water discharge port W Water body R Rust prevention layer 9 Conventional negative ion water generator 91 Tank 911 Through hole 92 Negative ion generator 921 Negative ion discharge port

Claims (22)

A negative ion water generator including a main body, a negative ion generator, an ultrasonic generator, a power supply module, and a container,
The negative ion generator is coupled to the main body, the negative ion generator is connected to a tube and an air pump, respectively, and the tube has a negative ion discharge port formed at an end away from the negative ion generator,
The ultrasonic generator is coupled to the main body, and the ultrasonic generator is connected to a vibrating body from a rod.
The power supply module is coupled to the body, and the power supply module is electrically connected to the negative ion generator, an air pump, and an ultrasonic generator, respectively.
The container has an opening, and the tube and the rod are formed from the opening so that the negative ion emission port of the negative ion generator and the vibrating body of the ultrasonic generator are formed inside the container. A negative ion water generator characterized by extending into a container.   The main body includes a stand and a pedestal, the stand is coupled to the pedestal, and the stand extends in a longitudinal direction away from the pedestal, and the negative ion generator and the ultrasonic generator are respectively The negative ion water generator according to claim 1, wherein the negative ion water generator is coupled to a stand.   The tube of the negative ion generator protrudes outside the stand of the main body, and extends to the pedestal along the longitudinal direction, the rod of the ultrasonic generator also protrudes outside the stand of the main body, and The negative ion water generator according to claim 2, wherein the negative ion water generator extends to the pedestal along the longitudinal direction.   The said container is installed adjacent to the base of the said main body, The negative ion water generator of Claim 3 characterized by the above-mentioned.   And a magnetizer, the magnetizer being a permanent magnet made of a hard magnetic material, the magnetizer being installed adjacent to a pedestal of the body, and along the longitudinal direction The negative ion water generator according to claim 3, which faces the tube and the rod.   The magnetizer according to claim 3, further comprising a magnetizer, wherein the magnetizer comprises an electromagnetic coil, and the magnetizer is coupled to the main body and is electrically connected to the power supply module. Negative ion water generator.   The pedestal of the main body has a mounting surface, the mounting surface faces the tube of the negative ion generator and the rod of the ultrasonic generator along the longitudinal direction, and the magnetizer It installs in the position adjacent to a mounting surface, The negative ion water generator of Claim 6 characterized by the above-mentioned.   The said container is installed in the mounting surface of the said base, The negative ion water generator of Claim 7 characterized by the above-mentioned.   The power supply module includes a power supply line, and the power supply line is used for electrical connection to a power supply external to the negative ion water generator. Negative ion water generator described in 1.   The container is connected to a water discharge pipe, an end of the water discharge pipe communicates with a water discharge port, the water discharge pipe further includes a magnetizer, and the magnetizer includes a permanent magnet, and the permanent magnet The negative ion water generator according to claim 4, wherein the negative ion water generator is installed in the water discharge pipe and has a magnetic field strength of 3000 to 5000 Gs.   The negative ion water generator according to claim 10, wherein the permanent magnet has a magnetic field strength of 4000 ± 10% Gs.   The said permanent magnet is installed in the outer periphery of the said water discharge pipe, The negative ion water generator of Claim 10 or Claim 11 characterized by the above-mentioned.   The negative ion water generator according to claim 12, wherein a magnetic pole surface of the permanent magnet is fixed by being bonded to an outer peripheral wall of the water discharge pipe.   The negative ion water generator according to claim 13, wherein a coupling surface is provided on an outer peripheral wall of the water discharge pipe, and a magnetic pole surface of the permanent magnet is bonded to the coupling surface.   The magnetizer includes a magnetic field blocking member, and the magnetic field blocking member covers the permanent magnet so that one magnetic pole surface of the permanent magnet is exposed and bonded to the water discharge pipe. Item 14. The negative ion water generator according to Item 13.   The negative ion water generator according to claim 15, wherein the magnetizer has a cover, and the cover covers the magnetic field blocking member.   The negative ion water generator according to claim 16, further comprising a rust prevention layer between the magnetic field shielding member and the cover.   The negative ionic water generator according to claim 17, wherein the rust prevention layer is formed on an outer surface of the magnetic field shielding member or an inner surface of the cover.   The magnetizer includes at least one fixing member, and the fixing member is in contact with the cover so that the permanent magnet, the magnetic field blocking member, and the cover are firmly bound to the water discharge pipe. The negative ion water generator according to claim 16.   The minus according to claim 13, wherein the magnetizer further includes another permanent magnet, and the two permanent magnets are spaced apart along the outer peripheral wall of the water discharge pipe. Ionized water generator.   21. The negative ion water generator according to claim 20, wherein the two permanent magnets are disposed opposite to each other with different magnetic poles in the radial direction of the water discharge pipe. The negative ion water generator according to claim 13, wherein a surface of the permanent magnet to be bonded to the water discharge pipe is a curved surface.