JP2016215162A - Device for charging atomized liquid with minus charge and releasing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for atomizing liquid and releasing the atomized liquid which is simple, has minimized power consumption and is excellent in deodorant ability, aroma diffusion capability and sterilization ability.SOLUTION: A needle electrode 3 by which a minus high voltage is applied is provided in a container 1 having a release port 2 on an upper part, a first cylinder electrode 4 is provided on the lower side of the needle electrode, a second cylinder electrode 5 having a release port on the tip is provided on the upper side of the needle electrode, a suction port 6 is opened on a lateral surface of the container, a duct 7 which is communicated to the first cylinder electrode from the suction port is provided, a liquid storing part 9 is provided on the lower side of the first cylinder electrode, corona discharge is performed between a lower end 32 of the needle electrode and the first cylinder electrode, an ion wind of downward flow proceeding from the suction port to the liquid storing part is generated, further, corona discharge is performed between an upper end 31 of the needle electrode and the second cylinder electrode, by utilizing an ion wind of upward flow proceeding from liquid surface to the release port, liquid is vaporized, atomized, at the same time, is charged and is released from the release port.SELECTED DRAWING: Figure 1

Description

The present invention relates to an apparatus for discharging a micronized liquid with a negative charge.

Devices that atomize and release liquids containing deodorants, fragrances, disinfectants, and the like are known.
For example, a tank to which a deodorant liquid is supplied, an atomizer for atomizing the deodorant liquid, and a nozzle for spraying the atomized deodorant liquid in the tank to predetermined air are provided. A deodorizing system has been proposed (see Patent Document 1).

However, in this deodorizing system, “the air pump 30 is operated based on a command from the control panel 40, and the deodorant liquid 3 in the tank 2 is atomized by the atomizer 25. The atomized deodorant in this way. The liquid 3 is transported by the transport pipe 35 and sprayed from the nozzle 36. Therefore, the air can be deodorized by spraying the deodorant liquid 3 on the predetermined air from the nozzle 36. (See paragraph 0020 of Patent Document 1), and the system is quite large as a whole.

There has also been proposed an electric fragrance diffuser comprising a tank for storing water containing essential oils for aromatherapy, a fan blade for sucking and introducing air into the tank, an electric motor for rotating the fan blade, and the like. (See Patent Document 2).
Furthermore, an ultrasonic fragrance diffuser in which an ultrasonic vibrator is arranged has also been proposed (see, for example, Patent Document 3).
However, these fragrance diffusers need to use a motor such as a fan or an ultrasonic generator.

As described above, the conventionally proposed apparatus is a considerably large system, or requires a motor such as a fan or an ultrasonic generator, so that power consumption is required to some extent. Because it is simpler and consumes much less power, and it has a high ability to atomize and release liquid, it can be excellent in deodorizing ability, aroma diffusion ability and disinfection ability. There is a need for a device that can be converted into a discharge.

Japanese Patent No. 3495124 JP 2004-147799 A Utility Model Registration No. 3157629

The present invention solves the above-mentioned conventional problems, does not require the use of motors such as fans or ultrasonic generators, is simpler, consumes significantly less power, and has the ability to atomize and discharge liquids. An object of the present invention is to provide an apparatus for atomizing and releasing a liquid, which can be excellent in deodorizing ability, aroma diffusing ability, sterilizing ability, and the like because of its high level.

The present invention relates to the following (1) to (3).
(1): In a container having a discharge port at the top;
A needle electrode to which a negative high voltage is applied with both ends of the needle facing up and down;
Providing a first cylindrical electrode below the needle electrode;
Provided above the needle electrode is a second cylindrical electrode having the discharge port at the tip;
Opening a suction port on the side of the container;
Providing a duct leading from the suction port to the first cylindrical electrode;
Exposing a lower portion of the needle electrode in the duct;
Providing a liquid reservoir below the first cylindrical electrode;
In the duct, a corona discharge is generated between the lower end of the needle electrode and the first cylindrical electrode, and the liquid that passes through the first cylindrical electrode from the suction port and is stored in the liquid storage portion. Creating a downward ionic wind towards the surface; and
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and passes upward from the liquid surface stored in the liquid storage part to the discharge port through the second cylindrical electrode. Creating a counter-current ionic wind;
Using the downward flow of ionic wind to evaporate and atomize the liquid stored in the liquid reservoir, and to charge the atomized liquid with a negative charge;
Utilizing the ionic wind of the upward flow, the atomized and negatively charged liquid is raised and discharged to the outside from the discharge port at the tip of the second cylindrical electrode;
The present invention relates to a device for discharging a atomized liquid with a negative charge.

(2): The apparatus according to (1), wherein the liquid includes one or more components selected from an aroma component, a sterilizing component, and a deodorizing component.

(3): The apparatus according to (1) or (2), wherein the diameter of the first cylindrical electrode is larger than the diameter of the second cylindrical electrode.

According to the device for applying a negative charge to the atomized liquid according to the present invention (hereinafter, simply referred to as “device of the present invention”), the device is simple and consumes significantly less power.
Moreover, since the device of the present invention has a high ability to atomize and release a liquid, when it is used as a deodorizing device, aroma diffusing device, a sterilizing device, etc., a deodorizing capability, aroma diffusing capability, a sterilizing capability, There is also provided a device for discharging a atomized liquid with a negative charge that can be excellent.

According to the apparatus of the present invention, the atomized liquid can be negatively charged and can be efficiently discharged into a space such as air.
The atomized liquid (droplet) to be discharged is negatively charged, and after being discharged, it goes to a place where it is positively charged.
In a general room, people, clothes, wallpaper, curtains, etc. are easily charged positively.
Accordingly, the atomized liquid (droplet) having a negative charge discharged by the apparatus of the present invention is directed to a positively charged person, clothes, wallpaper, curtain, or the like.
Therefore, according to the apparatus of the present invention, when a liquid containing one or more components selected from a fragrance component, a sterilizing component, and a deodorizing component is used as a liquid, a finely divided liquid containing these components ( Droplets) can be directed to places where fragrance, sterilization, deodorization, etc. are necessary.
Therefore, compared with the case where the atomized liquid (droplet) released into the air is usually merely floating in a space such as the air, the device of the present invention is fragrant to a person. Can be strengthened, and sterilization and deodorization can be made more effective.

It is explanatory drawing which shows the principle of the apparatus which concerns on this invention. It is explanatory drawing seen from the front which shows one Embodiment of the apparatus which concerns on this invention. It is explanatory drawing seen from the back surface which shows one Embodiment of the apparatus which concerns on this invention. It is explanatory drawing seen from the plane which shows one Embodiment of the apparatus which concerns on this invention. It is explanatory drawing seen from the bottom face which shows one Embodiment of the apparatus which concerns on this invention. It is explanatory drawing seen from the right side surface which shows one Embodiment of the apparatus which concerns on this invention. It is explanatory drawing seen from the left side surface which shows one Embodiment of the apparatus which concerns on this invention. FIG. 8 is a cross-sectional explanatory view of FIG. 7. It is a perspective view which shows one Embodiment of the apparatus which concerns on this invention. It is the perspective view which looked at FIG. 9 from another angle. It is decomposition | disassembly explanatory drawing of FIG. It is perspective explanatory drawing which shows an example of the components (intermediate part outer container) near suction inlet when the apparatus which concerns on this invention is decomposed | disassembled into the components which comprise this. It is perspective explanatory drawing which looked at the components shown in FIG. 12 from another angle.

The present invention relates to a device for discharging a micronized liquid with a negative charge,
In a container with an outlet at the top;
A needle electrode to which a negative high voltage is applied with both ends of the needle facing up and down;
Providing a first cylindrical electrode below the needle electrode;
Provided above the needle electrode is a second cylindrical electrode having the discharge port at the tip;
Opening a suction port on the side of the container;
Providing a duct leading from the suction port to the first cylindrical electrode;
Exposing a lower portion of the needle electrode in the duct;
Providing a liquid reservoir below the first cylindrical electrode;
In the duct, a corona discharge is generated between the lower end of the needle electrode and the first cylindrical electrode, and the liquid that passes through the first cylindrical electrode from the suction port and is stored in the liquid storage portion. Creating a downward ionic wind towards the surface; and
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and passes upward from the liquid surface stored in the liquid storage part to the discharge port through the second cylindrical electrode. Creating a counter-current ionic wind;
Using the downward flow of ionic wind to evaporate and atomize the liquid stored in the liquid reservoir, and to charge the atomized liquid with a negative charge;
Utilizing the ionic wind of the upward flow, the atomized and negatively charged liquid is raised and discharged to the outside from the discharge port at the tip of the second cylindrical electrode;
It is characterized by this.

Hereinafter, an embodiment of an apparatus for applying a negative charge to a atomized liquid and releasing it according to the present invention will be described in detail with reference to the drawings.
FIG. 1 is an explanatory view showing the principle of the apparatus according to the present invention. The arrows in FIG. 1 indicate the flow of ion wind.
Moreover, FIG. 2 is explanatory drawing seen from the front which shows one Embodiment of the apparatus based on this invention, FIG. 3 is explanatory drawing seen from the back, FIG. 4 is explanatory drawing seen from the plane, FIG. 5 is an explanatory diagram viewed from the bottom, FIG. 6 is an explanatory diagram viewed from the right side, and FIG. 7 is an explanatory diagram viewed from the left side. FIG. 8 is a cross-sectional explanatory view of FIG.
However, all the drawings are schematic views showing the apparatus of the present invention. Therefore, when commercializing, a more practical design can be made as needed.

In the figure, reference numeral 1 denotes a container, and a discharge port 2 is provided on the top of the container 1.
In the present embodiment, the container 1 has a tubular shape, more specifically, a cylindrical tubular shape, but is not limited to this without departing from the spirit of the present invention, for example, a rectangular tubular shape. You can also

In such a container 1, a needle electrode 3 is provided with both ends of the needle facing in the vertical direction.
A high voltage, in particular a negative high voltage, is applied to the needle electrode 3. This is because a negative discharge is easier to obtain an ion wind with a higher flow rate than a positive discharge. However, if necessary, a positive high voltage can be applied.
By applying a negative high voltage to the needle electrode 3, corona discharge can be generated from the sharp tip (each of the upper end 31 and the lower end 32) of the needle electrode 3.
In order to apply a high voltage to the needle electrode 3, although not shown, a separate high voltage power supply device is provided and connected to the needle electrode 3.

Note that a negative high voltage direct current of −4,000 V to −15,000 V is applied from the high voltage power supply device. However, as described above, a positive high-voltage direct current, particularly a positive high-voltage direct current of 4,000 to 15,000 V, can be applied as necessary.

Below the needle electrode 3, specifically, below the lower end 32 of the needle electrode 3, a first cylindrical electrode 4 (lower cylindrical electrode 4) is provided above the bottom surface 11 of the container 1.

Further, above the needle electrode 3, specifically, above the upper end 31 of the needle electrode 3, below the discharge port 2, the second cylindrical electrode 5 (on the upper side) provided with the discharge port 2 at the tip. A cylindrical electrode 5) is provided.

Thus, in the apparatus of the present invention, the needle electrode 3 is divided into upper and lower cylindrical electrodes, that is, the first cylindrical electrode 4 (lower cylindrical electrode 4) and the second cylindrical electrode 5 (upper cylindrical electrode 5). It is common and prevents waste.
Normally, when a negative high voltage (−4,000 to −15,000 V) is applied, the needle electrode 3 side becomes the positive side (anode), the first cylindrical electrode 4 (lower cylindrical electrode 4) and the first side The second cylindrical electrode 5 (upper cylindrical electrode 5) side is the negative side (cathode).

In this way, a high-voltage direct current is applied between the needle electrode 3, the first cylindrical electrode 4 (lower cylindrical electrode 4), and the second cylindrical electrode 5 (upper cylindrical electrode 5). As a result, corona discharge is performed between the needle electrode 3, the first cylindrical electrode 4 (lower cylindrical electrode 4), and the second cylindrical electrode 5 (upper cylindrical electrode 5). Ion winds flow from the needle electrode 3 side toward the second cylindrical electrode 5 (upper cylindrical electrode 5) toward the one cylindrical electrode 4 (lower cylindrical electrode 4). Yes.

Here, the first cylindrical electrode 4 (lower cylindrical electrode 4) and the second cylindrical electrode 5 (upper cylindrical electrode 5) are the same in terms of cylindrical electrodes, but as illustrated, their diameters are the same. And the length of the tube is different. In particular, the diameter of the first cylindrical electrode 4 (lower cylindrical electrode 4) is preferably larger than the diameter of the second cylindrical electrode 5 (upper cylindrical electrode 5). Electrons (e−) emitted from the cylindrical electrode 4 (lower cylindrical electrode 4) are transferred to the liquid surface. Can be applied in a wide angle (over a wide range). However, if necessary, the diameter and the length of the tube can be the same.

That is, first, the first cylindrical electrode 4 (lower cylindrical electrode 4) applies the emitted electrons (e−) to the surface of the liquid stored in the liquid storage portion 9 described later in a wide angle. In order to promote the reaction of transpiration and atomization, the diameter is relatively large and the length of the cylinder is also relatively short.
On the other hand, the second cylindrical electrode 5 (upper cylindrical electrode 5) reliably charges the liquid (droplet) atomized as described above and ejects the liquid in a laminar flow. Therefore, the diameter is made smaller than that of the first cylindrical electrode 4 (lower cylindrical electrode 4), the diameter is relatively small, and the length of the cylinder is the first cylindrical electrode 4 (lower cylindrical electrode 4). ) It is longer and the length of the cylinder is relatively long.

Below the needle electrode 3, a first cylindrical electrode 4 (lower cylindrical electrode 4) and a second cylindrical electrode 5 (upper cylindrical electrode 5) are respectively provided in a cylindrical shape and grounded. Corona discharge is generated between the needle electrode 3 and these two electrodes, respectively, and a downward flow (downflow) ion wind is generated between the needle electrode 3 and the first cylindrical electrode 4 (lower cylindrical electrode 4). Are generated between the needle electrode 3 and the second cylindrical electrode 5 (upper cylindrical electrode 5), respectively. In any case, a strong ion wind can be generated by using a cylindrical electrode.
Incidentally, the corona discharge is not a discharge in which a spark is scattered, and even if it touches the electrode during operation, it is of a level of static electricity and there is no concern about safety. If necessary, a known safety circuit can be appropriately incorporated.

Further, a suction port 6 is opened on the side surface 12 of the container 1.
The shape and structure in the vicinity of the suction port 6 are shown in detail in FIGS. 1, 2, 8, 9, 10, 11, 12, and 13, in particular.

A duct 7 leading from the suction port 6 opened in the side surface 12 of the container 1 to the first cylindrical electrode 4 (lower cylindrical electrode 4) is provided to form one flow path.
Thereby, the duct 7 is made to appear inside the tubular container 1 to form a so-called double tube structure.
That is, outside air is taken in through a duct 7 inside the suction port 6, and another flow path is formed between the outside of the duct 7 and the inside of the tubular container 1.

Only the lower part including the lower end 32 of the needle electrode 3 is exposed in the duct 7, and the upper part including the upper end 31 of the needle electrode 3 is not exposed in the duct 7.
For this reason, coupled with the formation of the two flow paths as described above, the second cylindrical electrode 5 (upper cylindrical electrode 5) exists above and below only one needle electrode 3. And the first cylindrical electrode 4 (lower cylindrical electrode 4).

Further, below the first cylindrical electrode 4 (lower cylindrical electrode 4), a liquid reservoir 9 containing a liquid 8 is provided.
The liquid storage unit 9 stores a liquid containing one or more components selected from a fragrance component, a sterilization component, and a deodorant component.
As these aromatic components, sterilizing components, and deodorizing components, known products such as those that are commercially available can be used.
For example, examples of the aromatic component include natural fragrances derived from plants, essential oils (essential oils), and aromatic oils containing synthetic fragrances in addition to these.

The device for discharging the atomized liquid with a negative charge according to the present invention can be produced by dividing it into several parts as shown in FIG. 8, FIG. 10, FIG. It can be left as a thing.

FIG. 8 is a cross-sectional explanatory view (FIG. 7) as viewed from the left side showing an embodiment of the apparatus of the present invention, and also shows components when disassembled.
Next, FIG. 9 is a perspective view showing an embodiment of the apparatus according to the present invention, and FIG. 10 is a perspective view of FIG. 9 seen from another angle. FIG. 11 is an exploded explanatory view of FIG.
Furthermore, FIG. 12 is a perspective explanatory view showing an example of a part (intermediate outer container) in the vicinity of the suction port when the apparatus according to the present invention is disassembled into parts constituting the apparatus, and FIG. 12 is a perspective explanatory view of the component shown in FIG.

The apparatus of the present invention comprises, in order from the top, a second cylindrical electrode 5 (upper cylindrical electrode 5), an upper outer container 13, an intermediate outer container 14 in which a suction port 6 is opened, and a lower outer container 15; The inner container 16 is accommodated in the lower outer container 15. The inner container 16 constitutes the liquid storage unit 9 described above.
A first cylindrical electrode 4 (lower cylindrical electrode 4) is provided on the upper portion of the inner container 16.
Further, the needle electrode 3 is attached to the needle electrode mounting portion 17 of the intermediate outer container 14 where the suction port 6 is open in the vertical direction, and the upper end 31 of the needle electrode 3 is located in the upper outer container 13. The lower end 32 of the needle electrode 3 is made to exist in the intermediate outer container 14 in which the suction port 6 is open.

In the apparatus of the present invention, corona discharge is made between the lower end 32 of the needle electrode 3 and the first cylindrical electrode 4 (lower cylindrical electrode 4) in the duct 7, and the first suction electrode 6 An ion wind of a downward flow (downflow) that passes through the cylindrical electrode 4 (lower cylindrical electrode 4) toward the liquid surface stored in the liquid storage unit 9 is generated.

On the other hand, in the apparatus according to the present invention, outside the duct 7, corona discharge is performed between the upper end of the needle electrode 3 and the second cylindrical electrode 5 (upper cylindrical electrode 5) and stored in the liquid storage unit 9. From the surface of the liquid, an upward flow (upward flow) ion wind that passes through the second cylindrical electrode 5 (upper cylindrical electrode 5) and travels toward the discharge port 2 is generated.

In the apparatus according to the present invention, the liquid stored in the liquid reservoir 9 is evaporated and atomized by using the downflow (downflow) ion wind generated by the corona discharge. The liquid is negatively charged.
That is, the above-described downward flow (downflow) ionic wind generated by corona discharge is applied to the liquid stored in the liquid storage unit 9 to evaporate the liquid and atomize the liquid. To charge.

Next, the above-described upward flow (upflow) ion wind generated by corona discharge is used to raise the atomized and negatively charged liquid to raise the second cylindrical electrode 5 (upper cylindrical electrode 5). ) Discharge from the discharge port 2 at the tip to the outside.
In this way, the atomized liquid is charged with a negative charge and released.

According to the apparatus of the present invention having the above configuration, it is not necessary to use motors such as fans or ultrasonic generators at all, and it is simpler and consumes significantly less power. The liquid can be atomized and released with excellent capability.

Further, the above-described apparatus for charging a fine atomized liquid with a negative charge and releasing it is combined with a humidifying air cleaning apparatus, and the function of discharging a finely charged liquid with a negative charge and a humidified air cleaning. And a function.
Here, as the humidified air cleaning device, a known device such as a commercially available one can be used and is not particularly limited.
In this way, when the atomized liquid is charged with a negative charge and released, and the humidified air cleaning device is provided, both devices can be operated together or separately. It can be selected appropriately according to various conditions such as season and time.

As described above, the present invention has been described in various ways with preferred embodiments. However, the present invention is not limited to these embodiments, and many modifications can be made without departing from the spirit of the present invention. It is a matter of course.

Here, when the device for applying a negative charge to the atomized liquid according to the present invention and applying it to a device for releasing a fragrance component (fragrance diffusing device), for example, a motor such as a fan, an ultrasonic generator, etc. It is simpler, consumes less power, is more efficient, has a stronger fragrance effect, and can be used in a wide range of fields such as aromatherapy and prevention of dementia. It is expected to be used in.

1 container 2 discharge port 3 needle electrode 4 first cylindrical electrode (lower cylindrical electrode)
5 Second cylindrical electrode (upper cylindrical electrode)
6 Suction Port 7 Duct 8 Liquid 9 Liquid Storage Unit 11 Bottom of Container 1 12 Side of Container 1 13 Upper Outer Container 14 Middle Outer Container 15 Lower Outer Container 16 Inner Container 17 Needle Electrode Mounting Section 31 Upper End of Needle Electrode 32 Needle Electrode Bottom edge of

Here, the first cylindrical electrode 4 (lower cylindrical electrode 4) and the second cylindrical electrode 5 (upper cylindrical electrode 5) are the same in terms of cylindrical electrodes, but as illustrated, their diameters are the same. And the length of the tube is different. In particular, the diameter of the first cylindrical electrode 4 (lower cylindrical electrode 4) is preferably larger than the diameter of the second cylindrical electrode 5 (upper cylindrical electrode 5). Electrons (e−) emitted from the cylindrical electrode 4 (lower cylindrical electrode 4) can be applied to the liquid surface in a wide angle (in a wide range). However, if necessary, the diameter and the length of the tube can be the same.

Claims (3)

In a container with an outlet at the top;
A needle electrode to which a negative high voltage is applied with both ends of the needle facing up and down;
Providing a first cylindrical electrode below the needle electrode;
Provided above the needle electrode is a second cylindrical electrode having the discharge port at the tip;
Opening a suction port on the side of the container;
Providing a duct leading from the suction port to the first cylindrical electrode;
Exposing a lower portion of the needle electrode in the duct;
Providing a liquid reservoir below the first cylindrical electrode;
In the duct, a corona discharge is generated between the lower end of the needle electrode and the first cylindrical electrode, and the liquid that passes through the first cylindrical electrode from the suction port and is stored in the liquid storage portion. Creating a downward ionic wind towards the surface; and
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and passes upward from the liquid surface stored in the liquid storage part to the discharge port through the second cylindrical electrode. Creating a counter-current ionic wind;
Using the downward flow of ionic wind to evaporate and atomize the liquid stored in the liquid reservoir, and to charge the atomized liquid with a negative charge;
Utilizing the ionic wind of the upward flow, the atomized and negatively charged liquid is raised and discharged to the outside from the discharge port at the tip of the second cylindrical electrode;
A device for discharging a atomized liquid with a negative charge.
The device according to claim 1, wherein the liquid includes one or more components selected from an aroma component, a sterilization component, and a deodorizing component.
  The apparatus according to claim 1 or 2, wherein the diameter of the first cylindrical electrode is larger than the diameter of the second cylindrical electrode.

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