JP2017080063A - Device of atomizing and discharging water-soluble chemical - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device in which the discharge speed of a chemical included in a gel-shaped chemical is swift, and discharge speed can be changed.SOLUTION: Provided is a device for atomizing a water-soluble chemical where the inside of a container 1 having a discharge port 2 at the upper part is provided with a needle electrode 3 applied with minus high voltage, the lower part of the needle electrode 3 is provided with the first cylindrical electrode 4, and the upper part thereof is provided with the second cylindrical electrode 5. A duct 7 communicated from a suction port 6 to the first cylindrical electrode 4, the lower part of the first cylindrical electrode 4 is provided with a gel-shaped chemical storage part 9, corona discharge is generated between the lower edge 32 of the needle electrode 3 and the first cylindrical electrode 4 to cause ionic wind of downflow passing through the first cylindrical electrode 4 from the suction port 6 and going to the surface of a gel-shaped chemical 8 stored in the gel-shaped chemical storage part 9, corona discharge is performed between the upper edge 31 of the needle electrode 3 and the second cylindrical electrode 5 to cause ionic wind of upflow, and a water-soluble chemical included in the gel-shaped chemical 8 stored in the gel-shaped chemical storage part 9 is transpired and pulverized to discharge the pulverized matter from the discharge port 2 at the tip 5 of the second cylindrical electrode to the outside.SELECTED DRAWING: Figure 1

Description

The present invention relates to an apparatus for atomizing and releasing a water-soluble drug, and in particular, atomizes and evaporates a water-soluble drug (aroma component, disinfectant component, deodorant component) incorporated in a gel-like drug. The present invention relates to an apparatus for atomizing and discharging as atomized material.

Conventionally, liquid deodorants, fragrances, disinfectants and the like have been used in many cases.
However, for example, in the case of an automobile deodorant, fragrance, disinfectant, etc., if it is liquid, the contents may leak due to vibration, etc. In some cases, a solid or semi-solid state such as a gel is desirable (see Patent Document 1).

As gel-like fragrances and deodorants, for example, fragrances and deodorizers made of gel-like agents in which water-soluble agents (such as fragrance ingredients) are soaked in gelling agents such as carrageenan and agar are known. In recent years, a highly water-absorbing resin (a highly water-absorbing polymer) has been used as a gelling agent (see, for example, Patent Documents 1 and 2).

However, in a conventional fragrance container containing such gel-like fragrance or deodorant, the release (diffusion) rate is not sufficient, or the release (diffusion) rate can be freely changed. Therefore, the improvement has been desired (for example, refer to the prior art in Patent Document 3).

JP 2002-80681 A JP-A-6-39023 Japanese Patent Laid-Open No. 9-299469

The present invention solves the above-mentioned conventional problems, and the release (diffusion) rate of the water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in the gel-like drug is sufficiently high, and the gel It is an object of the present invention to provide a device capable of freely changing the release (diffusion) rate of a water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in a liquid drug.

The present invention relates to the following (1) to (9).
(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 gel-like medicine container under the first cylindrical electrode;
In the duct, corona discharge is made between the lower end of the needle electrode and the first cylindrical electrode, passes through the first cylindrical electrode from the suction port, and is stored in the gel-like drug storage unit. Creating a down-flowing ionic wind towards the gelled drug surface;
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and the discharge port passes through the second cylindrical electrode from the surface of the gel-like drug stored in the gel-like drug storage unit. Creating an up-flowing ionic wind towards
Using the downward-flowing ionic wind, the water-soluble drug taken in the gel-like drug stored in the gel-like drug storage unit is evaporated and atomized to form a fine product;
Utilizing the upward-flowing ionic wind, the atomized product is raised and discharged to the outside from the discharge port at the tip of the second cylindrical electrode;
It is characterized by
The present invention relates to a device for atomizing and releasing a water-soluble drug incorporated in a gel drug.

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

(3): The apparatus according to (1) or (2), wherein the gelled drug is a gelling agent incorporating a water-soluble drug.

(4): The gelling agent is one or more selected from the group consisting of a superabsorbent resin, carrageenan, locust bean gum, agar, gelatin, guar gum, gellan gum, pectin, and xanthan gum. This relates to the apparatus described in 3).

(5): The apparatus according to (3), wherein the gel-like drug is a bead-like substance that is soaked in a highly water-absorbent resin with a water-soluble drug.

(6): The apparatus according to any one of (1) to (5), wherein the water-soluble drug includes one or more components selected from an aroma component, a sterilizing component, and a deodorizing component. It is about.

(7): The apparatus according to any one of (1) to (6), further including a control unit for controlling the release of the water-soluble drug incorporated in the gel-like drug.

(8): The control means controls the release of the water-soluble drug incorporated in the gel-like drug by making the application of a negative high voltage to the needle electrode variable. This relates to the device described in (7).

(9): The control means controls the release of the water-soluble drug incorporated in the gel drug by intermittently applying a negative high voltage to the needle electrode. This relates to the device described in (7).

The device according to the present invention provides a release device having a high release (diffusion) rate of a water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in a gel drug.
Therefore, when this is used as a deodorizing device, a fragrance diffusing device, a sterilizing device or the like, the odor eliminating ability, the fragrance diffusing ability, the sterilizing ability, etc. are excellent.

Further, according to the apparatus of the present invention, the release (diffusion) rate of the water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in the gel-like drug can be freely changed. A possible discharge device is provided.

The device according to the present invention does not require any motor such as a fan or an ultrasonic generator, is simpler and consumes much less power, and has excellent deodorizing ability, fragrance diffusing ability, sterilizing ability, etc. It is a thing.

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. It is center part longitudinal cross-section explanatory drawing of FIG. It is a perspective explanatory view showing one embodiment of the device concerning the present invention. In the perspective explanatory view showing an embodiment of the apparatus according to the present invention shown in FIG. 9, the lower container 15 is pulled out, and the gel-like medicine 8 stored in the gel-like medicine storage part 9 in the lower container 15 is drawn. It is a perspective explanatory view showing the state taken out. In FIG. 10, the gel-like medicine 8 taken out from the gel-like medicine container 9 in the lower container 15 is returned to the gel-like medicine container 9 in the lower container 15, and this lower container 15 is used as an apparatus according to the present invention. It is perspective explanatory drawing which showed the mode to return to to by the arrow. It is perspective explanatory drawing which shows an example of the components (intermediate part container 14) of the suction inlet vicinity 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. 6 is a photographic image diagram showing test results in Test Example 1. FIG.

The present invention relates to a device for atomizing and releasing a water-soluble drug incorporated in a gel drug,
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 gel-like medicine container under the first cylindrical electrode;
In the duct, corona discharge is made between the lower end of the needle electrode and the first cylindrical electrode, passes through the first cylindrical electrode from the suction port, and is stored in the gel-like drug storage unit. Creating a down-flowing ionic wind towards the gelled drug surface;
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and the discharge port passes through the second cylindrical electrode from the surface of the gel-like drug stored in the gel-like drug storage unit. Creating an up-flowing ionic wind towards
Using the downward-flowing ionic wind, the water-soluble drug taken in the gel-like drug stored in the gel-like drug storage unit is evaporated and atomized to form a fine product;
Utilizing the upward-flowing ionic wind, the atomized product 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 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 an explanatory diagram of a longitudinal section at the center of FIG. 3 (an AA sectional view of FIG. 5). FIG. 9 is a perspective explanatory view showing an embodiment of an apparatus according to the present invention.
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.

As described above, in the apparatus according to 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). To prevent 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) 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.

That is, first, the first cylindrical electrode 4 (lower cylindrical electrode 4) causes the emitted electrons (e−) to be deposited on the surface of the gel-like drug 8 housed in the gel-like drug container 9 described later. In order to accelerate the reaction to atomize and evaporate the water-soluble drug taken in the gel-like drug 8 by wide-angle application, 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) is surely charged with a negative charge with respect to the water-soluble medicine atomized and evaporated as described above, and In order to eject by laminar flow, the diameter is made smaller than 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 It is longer than the cylindrical electrode 4) on the side, 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, 10, 11, 12, and the like.

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), there is provided a gel-like medicine storage portion 9 that stores the gel-like medicine 8.
The gel drug is a combination of a gelling agent and a water-soluble drug, and is used in a form in which the water-soluble drug is incorporated into the gelling agent by incorporating the water-soluble drug into the gelling agent. Is.
As the gelled drug 8, for example, a gelling agent in which a water-soluble drug is incorporated is used. However, the gelling drug 8 is not limited to this, and the gelling drug and the water-soluble drug are arranged separately. May be opened so that the water-soluble drug is taken into the gelling agent.

Here, examples of the gelling agent include a superabsorbent resin, carrageenan, locust bean gum, agar, gelatin, guar gum, gellan gum, pectin, xanthan gum and the like. In the present invention, one of these is used. These can be used alone or in combination of two or more thereof.

Among these, the super absorbent polymer (abbreviated as SAP) is also called super absorbent polymer or super absorbent polymer, and is a highly absorbent polymer that absorbs a large amount of water to gel and retains the absorbed water. It is a molecular material.
Examples of the highly water-absorbent resin (superabsorbent polymer) include synthetic polymer-based materials such as polyacrylic acid-based resins; and those derived from natural products such as starch-based and cellulose-based materials. Any of these can be used.

Among highly water-absorbent resins, polyacrylic acid resins, especially polyacrylate resins such as sodium polyacrylate, are very hydrophilic and have a molecular structure that is crosslinked in a network structure and crosslinked in three dimensions. Therefore, it is a gel having high water absorption and water retention (having water absorption and water retention from several hundred times to about 1,000 times its own weight), and is preferably used in the present invention. However, since the polyacrylate resin has a high water absorption capacity and water retention capacity, water once absorbed has a characteristic that it hardly releases even if a certain pressure is applied.

The gel-like drug 8 is obtained by incorporating a water-soluble drug into the gelling agent as described above.
There is no restriction | limiting in particular as an aspect made into the gelatinous chemical | medical agent which has taken in the water-soluble chemical | medical agent in the above gelatinizers.
For example, when a highly water-absorbing resin is used as a gelling agent, the water-absorbing resin is soaked in the water-absorbing agent and then inflated into a bead shape. It is possible to obtain a “bead-shaped gel-like drug” soaked with a water-soluble drug. In addition to beads, gelled drugs of various shapes such as powder and strip can be obtained.
As described above, a gelled drug using a highly water-absorbing resin as a gelling agent is capable of gradually releasing the water-soluble drug incorporated therein by, for example, being soaked in the gelled drug. It can be done.

According to the apparatus according to the present invention, the gel-like medicine stored (placed) in the gel-like medicine storage section 9 (mounting section) using the downward-flowing ionic wind generated by corona discharge. The water-soluble drug incorporated in the water 8 is atomized and evaporated to be atomized to obtain a atomized product, and further, the above-mentioned atomized product is raised using the upward flow (upward flow) ion wind. Since the discharge from the discharge port at the tip of the second cylindrical electrode 5 is released to the outside, the release (diffusion) rate of the water-soluble drug (aroma component, disinfectant component, deodorant component) incorporated in the gel drug is increased. You can speed up. Therefore, when this is used as a deodorizing device, a fragrance diffusing device, a sterilizing device or the like, the odor eliminating ability, the fragrance diffusing ability, the sterilizing ability, etc. are excellent. Furthermore, according to the apparatus of the present invention, the release (diffusion) rate of the water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in the gel-like drug can be freely changed. it can.

For example, when carrageenan, locust bean gum, agar, gelatin, guar gum, gellan gum, pectin, xanthan gum or the like is used as a gelling agent, these are absorbed and taken in together with a water-soluble drug. Since it gels, a water-soluble medicine can be taken into such a gelling agent by mixing them.

Here, a water-soluble chemical | medical agent contains 1 or more types of components chosen from the aromatic component, the microbe elimination component, and the deodorizing component.
Therefore, a water-soluble drug containing at least one component selected from an aroma component, a sterilizing component, and a deodorizing component is incorporated into the gel-like drug.
Therefore, in this gel-like medicine storage section 9, a gel-like medicine in which a water-soluble medicine containing at least one component selected from a fragrance component, a sterilizing component, and a deodorizing component is incorporated in the gelling agent. 8 is stored.

As these aromatic components, sterilizing components, and deodorizing components, known products such as those that are commercially available can be used.
Here, 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.
Examples of the sterilizing component include chlorine dioxide and hypochlorous acid.
Furthermore, examples of the deodorizing component include sodium bicarbonate, citric acid, catechin, platinum, and plant extracts.

As shown in FIG. 8, FIG. 10, FIG. 11, etc., the apparatus according to the present invention can be manufactured by dividing it into several parts and can be disassembled.

FIG. 8 is an explanatory view (FIG. 3) of a central portion of an explanatory view (FIG. 3) viewed from the rear, showing an embodiment of the apparatus according to the present invention, and is exploded. It is also a figure which shows the component at that time.
Next, FIG. 9 is a perspective explanatory view showing an embodiment of an apparatus according to the present invention.
FIG. 10 is a perspective explanatory view showing an embodiment of the apparatus according to the present invention shown in FIG. 9, in which the lower container 15 is pulled out and stored in the gel-like medicine storage unit 9 in the lower container 15. It is perspective explanatory drawing which shows the state which took out the gelatinous medicine 8 which has been removed.
Further, FIG. 11 shows that the gel medicine 8 taken out from the gel medicine container 9 in the lower container 15 is returned to the gel medicine container 9 in the lower container 15 in FIG. FIG. 3 is an explanatory perspective view showing a state of returning to the apparatus according to the present invention.

Furthermore, FIG. 12 is a perspective explanatory view showing an example of a part (intermediate container 14) 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.
FIG. 14 is a photographic image diagram showing the test results in Test Example 1.

The apparatus according to the present invention is divided into a second cylindrical electrode 5 (upper cylindrical electrode 5), an upper container 13, an intermediate container 14 having an inlet 6 open, and a lower container 15 in this order from the top. In the lower container 15, the above-described gel-like medicine storage unit 9 is provided. The gel-like medicine 8 is housed in the gel-like medicine housing portion 9 in the lower container 15.
A first cylindrical electrode 4 (lower cylindrical electrode 4) is provided on the upper part of the gel-like medicine storage unit 9.

In FIGS. 10 and 11, the gel-like medicine 8 is a cartridge type (cartridge cup), and is used by being stored and mounted in the gel-like medicine storage portion 9 in the lower container 15.
In the case of a cartridge type (cartridge cup), in use, the sealing member (seal member) attached to the surface of the gel type drug 8 of the cartridge type (cartridge cup) is removed to remove the gel type drug surface. Expose.

In addition, the said cartridge cup can be made into multiple, for example, a double thing, In this case, the kind and use of a gel-form chemical | medical agent can differ.
Specifically, for example, when the double type is used, it is easier to change the type of water-soluble drug, for example, a fragrance component, incorporated into the gel-like drug in the morning or evening than the single type. Become.

Further, as described above, the gel-like medicine 8 accommodated in the gel-like medicine accommodating portion 9 is obtained by incorporating the water-soluble medicine into the gelling agent.

As described above, the first cylindrical electrode 4 (lower cylindrical electrode 4) is provided on the upper part of the gel-like drug storage unit 9.
The needle electrode 3 is attached to the needle electrode mounting portion 17 of the intermediate container 14 in which the suction port 6 is open so as to face in the vertical direction, and the upper end 31 of the needle electrode 3 exists in the upper container 13. The lower end 32 of the needle electrode 3 is made to exist in the intermediate container 14 in which the suction port 6 is opened.

In the apparatus according to the present invention, in the duct 7, corona discharge is performed between the lower end 32 of the needle electrode 3 and the first cylindrical electrode 4 (lower cylindrical electrode 4), and the first through the suction port 6. The downward flow (downflow) ion wind that passes through the cylindrical electrode 4 (lower cylindrical electrode 4) toward the surface of the gel-like drug 8 stored in the gel-like drug 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 the gel-like drug storage unit 9. From the surface of the gel-like medicine 8 accommodated in the tube, an upward flow (upflow) ion wind that passes through the second cylindrical electrode 5 (upper cylindrical electrode 5) and travels toward the discharge port 2 is generated.

And in the apparatus which concerns on this invention, it is taken in into the gel-like chemical | medical agent 8 accommodated in the gel-like chemical | medical agent storage part 9 using the ion wind of the said downward flow (downflow) generated by the corona discharge. The water-soluble drug is atomized and evaporated to make fine particles.
At this time, this atomized product is negatively charged.
That is, the above-described downward flow (downflow) ionic wind generated by corona discharge is applied to the gel-like drug 8 stored in the gel-like drug storage unit 9 and is incorporated into the gel-like drug. The atomization and transpiration of the drug are atomized to form a atomized product, and the atomized product is negatively charged.

Next, the above-mentioned upward flow (upflow) ion wind generated by corona discharge is used to raise the atomized product (atomized product having a negative charge) to raise the second cylindrical electrode (upper side). Cylindrical electrode 5) Discharge from the discharge port 2 at the tip to the outside.
In this way, the water-soluble medicine taken in the gel-like medicine 8 is atomized, evaporated, and atomized (a finely charged substance having a negative charge) is released.

In the apparatus according to the present invention, since the ion wind generated by corona discharge is used, the release of the water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in the gelled drug 8 ( It is considered that the (diffusion) speed can be increased.
In particular, when a highly water-absorbing resin is used as a gelling agent, in general, the water-soluble drug incorporated in the network structure is not easily released but released little by little. In the apparatus according to the present invention, since the ion wind generated by corona discharge is used, the release of the water-soluble drug (aroma component, sterilization component, deodorant component) incorporated in the gelled drug 8 It is considered that the (diffusion) speed can be increased.
Further, in the apparatus according to the present invention, since a negative high voltage is applied and the atomized product is negatively charged, a highly water-absorbing resin (especially polyacrylic acid) is generated by the repulsive force of ions that are negative. It may be possible that the water-soluble drug incorporated in the network structure of the salt-based resin can be released more quickly.

The apparatus according to the present invention basically has the above-described configuration, and further has a control means for controlling the release of the water-soluble drug incorporated in the gel-like drug. can do.

As such a control means, for example, a means in which application of a negative high voltage to the needle electrode is made variable is cited. By making the voltage changeable in this way, it is possible to freely control (change) the “release”, more specifically, “release rate” of the water-soluble drug incorporated in the gel-like drug 8.

Examples of such control means include means (such as a timer switch) that intermittently applies a negative high voltage to the needle electrode.
In this way, by applying a negative high voltage to the needle electrode intermittently, the water-soluble drug taken into the gel-like drug 8 can be obtained without changing the release rate itself. Release (more specifically, the release amount) can be controlled (changed).

Furthermore, by combining the control means, the release rate of the water-soluble drug taken into the gel-like drug 8 can be freely controlled (changed), and the water-soluble drug taken into the gel-like drug 8 Can be controlled (changed).

According to the apparatus of the present invention having the above-described configuration, the water-soluble drug (fragrance component) incorporated in the gel-like drug 8 even though no motors such as a fan or an ultrasonic generator are used. , Disinfection component, deodorant component) release (diffusion) rate is fast and water-soluble drug (aroma component, disinfectant component, deodorant component) incorporated in the gel-like drug 8 is released (diffusion) rate There is provided an apparatus that can freely change the above.
Therefore, the device according to the present invention is simpler and consumes significantly less power than a device using a motor such as a fan or an ultrasonic generator. Moreover, it has excellent deodorizing ability, fragrance diffusing ability, and sterilizing ability.

In the present invention, since a solid or semi-solid gel drug is used, it is less affected by temperature / humidity than a method using a liquid drug or when it is naturally evaporated. Expected transpiration.
Further, the device according to the present invention can simplify the handling as compared with the case where a liquid medicine is used.
Next, for example, mere deodorant beads are recognized to evaporate in order from the surface layer portion, whereas in the apparatus according to the present invention, they are taken into the gel-like medicine stored in the gel-like medicine storage portion. The water-soluble drug that is being supplied can be supplied and evaporated from the deeper part of the surface layer by transpiration of the surface layer with a stable amount of transpiration according to the surface area of the lower container constituting the tray. Can do.
According to the device of the present invention, it is possible to release the water-soluble drug that has been neatly taken into the gel drug.

Furthermore, the above-described device according to the present invention can be combined with a humidified air cleaning device or the like.
Here, as the humidified air cleaning device, a known device such as a commercially available one can be used and is not particularly limited.
As described above, when the device according to the present invention and the humidified air cleaning device are provided, both devices may be operated together, or may be operated separately, and there are various seasons and times. According to conditions, it can select suitably.

The apparatus according to the present invention described above can be used in automobiles, bus bodies, and the like for automobiles in addition to being used indoors and indoors such as in homes, offices, and factories.
When the above-described device according to the present invention is mounted on a vehicle body or the like, the above-described device according to the present invention may be mounted in a case that covers the device.

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. Of course.

EXAMPLES The present invention will be described in detail below with reference to examples, but the scope of the present invention is not limited by these examples.

<Test Example 1>
A transpiration test of deodorant beads (manufactured by Este Co., Ltd.) in which a deodorant was incorporated into a highly water absorbent resin (sodium polyacrylate) was conducted.
Specifically, three transpiration tests were performed as follows.

First, using the apparatus shown in FIGS. 1 to 13, a transpiration test of deodorant beads incorporating a deodorant into a superabsorbent resin (sodium polyacrylate) was conducted for 24 hours, and a photograph after 24 hours. (Invention product).
The voltage, current, and power consumption of the direct current applied to the needle electrode 3 of the device were as follows.
・ Voltage: -7,000V
・ Current: 0.02 mA
・ Power consumption: 0.14Wh

For comparison, photographs were also taken of unused deodorant beads (Comparative product 1) and those naturally evaporated for 24 hours (Comparative product 2).

These results are shown in FIG. 14 (A, B, C) are photographic image diagrams showing test results in Test Example 1. FIG.
FIG. 14A is a photographic image showing the state of unused deodorant beads (comparative product 1), and FIG. 14B is the state of deodorized beads (comparative product 2) after 24 hours of natural evaporation. FIG. 14C is a photographic image diagram showing a state after 24 hours of the deodorant beads (product of the present invention) after being operated for 24 hours by the apparatus shown in FIGS.

From FIG. 14C, according to the apparatus shown in FIGS. 1 to 13, each deodorant bead is significantly smaller than the unused deodorant beads (Comparative Product 1) after 24 hours of operation. According to the invention, it can be seen that each deodorant bead was able to substantially evaporate the water-soluble drug that had absorbed water.
That is, according to the present invention, it is recognized that each deodorant bead was able to substantially evaporate the water-soluble drug absorbed by each particle in 24 hours.
In addition, the atomized water-soluble chemical | medical agent (deodorant) was discharge | released from the discharge port 2 of the apparatus shown in FIGS.

On the other hand, from FIG. 14B, the deodorant beads (comparative product 2) after 24 hours naturally evaporated are about 80 to 90% of the unused deodorant beads (comparative product 1). Most of the water-soluble drugs absorbed by the deodorant beads are still left.

As is apparent from FIGS. 14A, 14B and 14C, the size of the deodorant beads of the present invention shown in FIG. 14C is remarkably reduced.
Therefore, according to this invention, it turns out that the discharge | release apparatus with a quick discharge | release (diffusion) speed | velocity | rate of the water-soluble chemical | medical agent taken in in the deodorizing bead compared with natural transpiration is provided.

In addition, according to the apparatus of this invention, the atomized water-soluble chemical | medical agent can be tinged with a negative charge, and it can discharge | release efficiently in space, such as in the air.
That is, the atomized water-soluble drug to be released is negatively charged, and after being released, it goes to a place where it is positively charged.
In a general room, people, clothes, wallpaper, curtains, etc. are easily charged positively.
Thus, the negatively charged water atomized medicine released by the device of the present invention is directed to positively charged people, clothes, carpets, curtains and the like.
For this reason, according to the apparatus of the present invention, when the atomized water-soluble drug contains one or more components selected from a fragrance component, a sterilizing component, and a deodorizing component, The atomized water-soluble drug can be directed to a place where aroma, sterilization, deodorization and the like are necessary.
Therefore, compared with the case where the atomized water-soluble drug that is normally released into the air is merely floating in a space such as the air, the device of the present invention is fragrant. Can be strengthened, and sterilization and deodorization can be made more effective.

Here, when the device according to the present invention is applied to, for example, a device for releasing a fragrance component (fragrance diffusing device), it is not necessary to use a motor such as a fan or an ultrasonic generator at all, and it is simpler and consumes less power. It is remarkably small and efficient, and the release (diffusion) speed of fragrance components is high, which can enhance the effect of giving fragrances to humans, so it can be used in a wide range of fields such as aromatherapy and prevention of dementia. Is expected to do.
In addition, when the device according to the present invention is applied to, for example, a device (deodorant device) that releases a deodorant component, it is not necessary to use a motor such as a fan or an ultrasonic generator at all. In addition, it is extremely small and efficient, and the deodorizing component release (diffusion) speed is fast, so that the deodorizing effect can be strengthened.

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 Gel drug 9 Gel drug container 11 Bottom surface of container 12 Side surface of container 13 Upper container 14 Intermediate container 15 Lower container 17 Needle electrode mounting part 31 Upper end of needle electrode 32 Lower end of needle electrode

Claims (9)

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 gel-like medicine container under the first cylindrical electrode;
In the duct, corona discharge is made between the lower end of the needle electrode and the first cylindrical electrode, passes through the first cylindrical electrode from the suction port, and is stored in the gel-like drug storage unit. Creating a down-flowing ionic wind towards the gelled drug surface;
Corona discharge is made between the upper end of the needle electrode and the second cylindrical electrode, and the discharge port passes through the second cylindrical electrode from the surface of the gel-like drug stored in the gel-like drug storage unit. Creating an up-flowing ionic wind towards
Using the downward-flowing ionic wind, the water-soluble drug taken in the gel-like drug stored in the gel-like drug storage unit is evaporated and atomized to form a fine product;
Utilizing the upward-flowing ionic wind, the atomized product is raised and discharged to the outside from the discharge port at the tip of the second cylindrical electrode;
It is characterized by
A device that atomizes and releases water-soluble drugs incorporated in gel-like drugs.
The apparatus of claim 1, wherein the diameter of the first cylindrical electrode is greater than the diameter of the second cylindrical electrode.
The apparatus according to claim 1 or 2, wherein the gelled drug is a gelling agent incorporating a water-soluble drug.
The gelling agent according to claim 3, wherein the gelling agent is one or more selected from the group consisting of a superabsorbent resin, carrageenan, locust bean gum, agar, gelatin, guar gum, gellan gum, pectin, and xanthan gum. apparatus.
The device according to claim 3, wherein the gel-like drug is in the form of beads in which a water-soluble drug is taken into a superabsorbent resin.
The apparatus in any one of Claims 1-5 in which the said water-soluble chemical | medical agent contains 1 or more types of components chosen from the aroma component, the microbe elimination component, and the deodorizing component.
The device according to any one of claims 1 to 6, further comprising a control means for controlling the release of the water-soluble drug incorporated in the gelled drug.
The said control means controls discharge | release of the water-soluble chemical | medical agent taken in in the gel-like chemical | medical agent by making application of the minus high voltage to the said needle electrode variable. Equipment.
  The said control means controls discharge | release of the water-soluble chemical | medical agent taken in in the gel-like chemical | medical agent by performing the application of the minus high voltage to the said needle electrode intermittently. Equipment.