JP2003007426A - Ion feeder and space sterilization device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ion feeder which can supply stably a large quantity of positive and negative ions generated in the space. SOLUTION: Inside of a casing 2 having a suction port 2a and an air outlet 2b, the needle-shaped third electrode 7 and the meshed fourth electrode 8 are arranged and installed. The fourth electrode 8 is arranged and installed at an ion generator 101 side. A direct current electrode 9 arranged outside of the casing 2 is connected assuming the third electrode 7 as an electrode for voltage application and the fourth electrode 8 as an electrode for grounding. In this constitution, if a negative direct voltage is applied to the third electrode 7, an ion wind is generated by an electric field generated between the third and the fourth electrodes 7, 8. The positive and negative ions generated in the space by the action of the ion generator 101 are sent from the air outlet 2b to the outside of casing 2 by this wind.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ion sending device for sending artificially generated ions to a space and a space sterilizing device such as an air cleaner having the structure.

[0002]

2. Description of the Related Art In recent years, with the increasing airtightness of the living environment, there is an increasing demand to remove airborne bacteria harmful to the human body and to lead a healthy and comfortable life. In order to meet this demand, air cleaners having various filters have been developed.

[0003]

However, since such an air cleaner is of a type in which air in the space is sucked by a fan and contaminants are adsorbed or decomposed by a filter, it has a long service life. Maintenance such as replacement of the filter is indispensable, and since the characteristics of the filter are not sufficient, satisfactory performance is not always obtained.

On the other hand, an air cleaner for increasing the ion concentration in the air by using an ion generator has been developed, but the one currently on the market generates only negative ions. Although it can be expected that negative ions have a relaxing effect on humans, little effect has been observed on the active removal of airborne bacteria.

In view of such problems, the inventors of the present invention have
Previously, we developed an ion generator that generates positive ions and negative ions at the same time by applying a high-frequency AC voltage between electrodes facing each other across a dielectric, causing an ionization phenomenon such as discharge on the surface of the dielectric. . As positive ions, H ⁺ (H ₂
O) _n and O ₂ ⁻ (H ₂ O) _n are most stably generated as negative ions.

[0006] These ions, when positive ions or negative ions alone, have no remarkable effect on airborne bacteria in the air. However, when these ions are simultaneously produced, a chemical reaction occurs to generate hydrogen peroxide (H ₂ O ₂ ) or hydroxyl radical (.OH) which is an active species. Since this H ₂ O ₂ or .OH exhibits extremely strong activity, airborne bacteria in the air are decomposed and removed when they are released into the space.

However, the generated positive ions and negative ions are concentrated and stay in the very vicinity of the dielectric, and most of them recombine due to Coulombic interaction, and the concentration of the generated ions is reduced. . Therefore, there is a problem that desired sterilization performance cannot be obtained.

The present invention has been made in view of the above conventional problems, and an object of the present invention is to provide an ion feeding device capable of stably supplying a large amount of generated positive ions and negative ions. Another object of the present invention is to provide a space sterilizer having such a configuration of the ion feeding device.

[0009]

In order to achieve the above object, an ion sending apparatus of the present invention comprises an ion generating apparatus for generating positive ions and negative ions, and an electric field applying means for generating a positive or negative electric field in space. And the positive ions and the negative ions are sent by the wind generated by generating an electric field in the space by the electric field applying means.

In this case, the electric field applying means comprises a pair of electrodes, one of which is a voltage applying electrode and the other of which is a grounding electrode, and the grounding electrode is arranged on the side of the ion generator. . According to this, since the grounding electrode is arranged near the ion generator, the electrolysis generated by the electric field applying means does not adversely affect the ion generation state of the ion generator, and the ion generator is stable. This is preferable because positive ions and negative ions can be generated, and noise such as a blower does not occur during air blowing.

As the ground electrode, a mesh electrode having a mesh size of 9 to 24 mesh can be preferably used. According to this configuration, air resistance is not large, but electrolysis can be generated uniformly, so that a good blown state can be obtained.

When the voltage applied to the voltage applying electrode is a negative DC voltage, a negative electric field is generated in the space, electrons move from the voltage applying electrode to air molecules, and negative ions are generated. . This negative ion moves while being accelerated toward the grounding electrode side, so that wind occurs. Positive and negative ions are sent by this wind.

Further, the ion generating electrode according to the present invention has a casing having at least a suction port and a blowout port,
An ion generating device for generating positive ions and negative ions, and an electric field applying means comprising a pair of electrodes, one of which is a voltage applying electrode and the other of which is a grounding electrode, wherein the grounding electrode is arranged on the side of the ion generating device. Is provided in the space inside the casing that communicates the inlet and the outlet, by the wind generated by generating an electric field between the voltage applying electrode and the ground electrode by the electric field applying means, It is characterized in that the positive ions and the negative ions are sent.

In this case, when the electric field applying means is applied with an electric field having a polarity opposite to the polarity of the ions generated by the ion generating device, the negative ions or positive ions generated in the space by the operation of the ion generating device are generated. Ions are carried in the wind generated by the electric field generated by the electric field applying means,
Negative ions will be sent in a mixed state.

Further, the ion feeding device according to the present invention has first and second electrodes facing each other with an insulator interposed between them, and a third electrode facing the second electrode with a predetermined distance therebetween and facing each other. The second electrode is a grounding electrode, first AC voltage applying means connected to the first electrode for applying an AC voltage to the first electrode, and AC connected to the third electrode to the third electrode. Second alternating voltage applying means for applying a voltage,
The phase of the AC voltage applied to the first electrode by the first AC voltage applying means and the phase of the AC voltage applied to the third electrode by the second AC voltage applying means have opposite phases. Is characterized by.

According to this structure, when an AC voltage is applied to the first electrode, discharge occurs on the surface of the insulator, and positive and negative ions are generated in the space with the movement of electrons. At this time, since the phase of the alternating voltage applied to the third electrode is opposite to the phase of the first alternating voltage, the third electrode has a polarity opposite to that of the generated positive / negative ions. Therefore, the positive and negative ions move to the third electrode side while being accelerated, and are sent.

The ion feeder according to the present invention has a casing having at least a suction port and a blow port,
First and second electrodes facing each other with an insulator in between, and a third electrode facing the second electrode separated by a predetermined distance and facing each other
The first electrode is connected as a voltage applying electrode and the second electrode is connected as a grounding electrode, and is connected to a ground potential and a first AC voltage applying means for applying a first AC voltage to the first electrode. At the same time, the third electrode is connected as a voltage applying electrode, and second AC voltage applying means for applying a second AC voltage to the third electrode is provided inside the casing, and the suction port and the blower are provided. Provided in the space inside the casing that communicates with the outlet, by applying the phases of the first AC voltage and the second AC voltage as opposite phases,
It is characterized in that it has a mechanism for delivering positive ions and negative ions from the outlet.

According to this structure, when the first AC voltage is applied to the first electrode, discharge occurs on the surface of the insulator, and positive and negative ions are generated in the space with the movement of electrons. At this time, since the phase of the second AC voltage applied to the third electrode is opposite to the phase of the first AC voltage, the third electrode has a polarity opposite to that of the generated positive / negative ions. Become. Therefore, the positive and negative ions move to the third electrode side while being accelerated, and are sent to the outside of the casing from the air outlet.

Further, an ion sending device according to the present invention comprises a first ion sending device comprising a first electrode to which a voltage is applied and a second electrode which is a ground electrode facing the first electrode, and the first ion sending device. A second ion feeding device comprising a third electrode to which a voltage having a polarity opposite to that of the voltage applied to the electrode is applied, and a fourth electrode which is a grounding electrode facing the third electrode. It is characterized in that it is configured to mix and send out the ions sent from the first ion sending device and the ions sent from the second ion sending device.

The ion feeder according to the present invention comprises a casing having at least an inlet and an outlet, a first electrode to which a positive DC voltage is applied, and a grounding electrode provided opposite to the first electrode. A first ion feeding device including a certain second electrode and a third electrode which is insulated from the first ion feeding device and to which a negative DC voltage is applied; and a third electrode facing the third electrode. Fourth, which is a grounding electrode provided
A second ion feeding device including an electrode is arranged in a space inside the casing that communicates the suction port and the air outlet.

According to this, the positive ions sent from the first ion sending device and the negative ions sent from the second ion sending device are mixed and sent to the outside of the casing from the air outlet.

At this time, the voltage applied to at least one of the first electrode and the third electrode is adjustable so that the ratio of the positive and negative ions sent can be variously changed. It Therefore, when it is desired to obtain a large amount of either positive ions or negative ions, mutual switching can be easily performed.

According to the space sterilization apparatus having the above-mentioned structure, the bacteria in the space are sterilized and removed by the action of the active species generated when the positive ions and the negative ions are bound on the surface of the bacteria. .

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION <First Embodiment> First Embodiment of the Present Invention
Embodiments will be described with reference to the drawings. Figure 1
It is a schematic side cross-sectional view of the ion feeding device 1 according to the present embodiment. FIG. 2 is a perspective view showing a part of the ion generating device 101 in the ion feeding device 1 by crushing.
In FIG. 1, 2 is at least a suction port 2a and a blowout port 2b.
Is a casing of the ion feeding device 1 having, and is formed, for example, in a rectangular parallelepiped shape whose both ends are opened as a suction port 2a and a blowout port 2b. Reference numeral 3 is a dielectric provided inside the casing 2 on the side of the outlet 2b and for isolating the first and second electrodes 4 and 5 described later, for example, an inner diameter of 10 m.
A cylindrical Pyrex (R) glass tube having m, a thickness of 1.3 mm, and a length of 150 mm can be preferably used.

Inside the dielectric 3, as shown in FIG.
The first electrode 4 is arranged so as to be in close contact with the inner peripheral surface of the dielectric 3, and in the present embodiment, as an example thereof, a thickness of 0.8
A cylindrical electrode made of stainless steel SUS304 having a length of 80 mm and a length of 80 mm is used. The second electrode 5 is provided outside the dielectric 3.
Is arranged so as to be in close contact with the outer peripheral surface of the dielectric 3,
In the present embodiment, as an example thereof, a mesh-shaped cylindrical electrode having a wire diameter of 0.40 mm, a mesh size of 40 mesh, and a length of 80 mm is used. Thereby, the pair of first and second electrodes 4,
As shown in the figure, 5 are opposed to each other with the dielectric 3 interposed therebetween.

An AC power source 6 arranged outside the casing 2
Is connected to the first electrode 4 as a voltage application electrode and the second electrode 5 as a ground electrode. The second electrode 5 is connected as a ground potential between the first and second electrodes 4 and 5 from the AC power supply 6 An AC voltage having an effective value of 0.44 to 2.0 kV is applied. Then, the dielectric 3, the first and second electrodes 4 and 5, and the AC power source 6 constitute the ion generator 101 according to the present embodiment.

Further, the ion generator 1 in the casing 2
On the suction port 2a side of 01, a pair of third and fourth electrodes 7 as electric field applying means for generating a positive or negative electric field in the space,
8 are provided. The third electrode 7 is, for example, made of stainless SUS304 in which six needle-shaped portions 7a formed in a needle shape having a diameter of 1 mm, a length of 20 mm, and a tip curvature of 0.1 mm or less are projected in a line at intervals of 20 mm. Plate-shaped part 7b
Needle-shaped electrodes with can be used. The third electrode 7 need not be needle-shaped, and may be linear or mesh-shaped. However, since the applied voltage required to effectively generate the airflow increases in the order of needle-shaped, linear, and mesh-shaped, it is ideal to use a needle-shaped electrode from the viewpoint of energy saving.

The fourth electrode 8 has, for example, a wire diameter of 0.8 mm, an opening number of 9 to 24 mesh, and a size of 30 m.
A mesh electrode made of stainless steel SUS304 having a size of m × 150 mm can be preferably used. In the present embodiment, the casing is arranged so as to face the first electrode 7 at a distance of 10 mm from the tip of the needle-shaped portion 7a of the first electrode 7. It is attached to the inner wall of 2.
Here, the reason why the number of mesh openings is set to 9 to 24 mesh is that if the mesh size is smaller than 9 mesh, the mesh is too coarse and the accuracy of discharge tends to vary, and if it is larger than 24 mesh, the pressure loss becomes large. This will hinder the ventilation.

The fourth electrode 8 need only be fixed to the inner wall of the casing 2 at one place, and may not cover the entire cross section of the internal space of the casing 2.
When viewed from the suction port 2a side, at least the third electrode 7 needs to overlap and face. Further, in the present embodiment, the fourth electrode 8 is provided on the side of the ion generator 101.
Therefore, the second electrode 5 and the fourth electrode 8 are both at the ground potential. Therefore, since there is no potential difference between the adjacent second and fourth electrodes 5 and 8 and no electric field is generated, the wind generated by generating an electric field between the third and fourth electrodes 7 and 8 is smoothly ionized. It can be sent to the generator 101.

In the DC power supply 9 disposed outside the casing 2, the negative electrode is connected to the third electrode 7 as a voltage applying electrode, and the positive electrode is connected to the fourth electrode 8 as a grounding electrode, and the fourth electrode 8 is connected. A predetermined DC voltage is applied from the DC power supply 9 between the third and fourth electrodes 7 and 8 with the ground potential as the ground potential.

Next, an example of the operation of the ion feeding device 1 configured as described above will be described. An effective value of 1.5 k is applied to the first electrode 4 by using the AC power source 6 and setting the second electrode 5 to the ground potential.
While applying an AC voltage of V and a frequency of 20 kHz,
A negative DC voltage of −15 kV was applied to the third electrode 7 by using the DC power supply 9 with the second airflow generating electrode 8 set to the ground potential.

As a result, electric discharge occurs on the surface of the dielectric 3 separating the first and second electrodes 4 and 5, and positive and negative ions are generated, and an electric field is generated between the third and fourth electrodes 7 and 8. Occurs, electrons move from the tip of the needle-shaped portion 7a to air molecules, and the air molecules are negatively charged. This causes the charged air molecules to move toward the fourth electrode 8 side, which is at a relatively positive potential, while being accelerated. Therefore, a flow of air occurs in the casing 2, and wind that escapes from the suction port 2a to the air outlet 2b is generated. Riding on this wind, the ion generator 1
Positive ions and negative ions generated in the space by the operation of 01 are sent out of the casing 2 through the outlet 2b.

At this time, the concentrations of positive ions and negative ions sent from the outlet 2b were measured by an air ion counter arranged at a position 10 cm away from the dielectric 3 in the direction of the outlet 2b. Is 250,0
00 / cm ³ , negative ion concentration is 500,000 / c
m ³ and could be increased by an order of magnitude as compared with the case where no voltage was applied to the third electrode 7 (both positive and negative ions 25,000 / cm ³ ).

Therefore, according to the ion sending apparatus 1 of this embodiment, it is possible to send ions by the wind before the positive and negative ions generated in the space are neutralized and disappear. As a result, the positive and negative ions are attached to the surface of airborne bacteria, and the bacteria can be efficiently sterilized and removed by the action of the active species generated by the chemical reaction. Further, since the negative ions can be blown in a rich state, the effect of relaxing the human mood can be obtained as a synergistic effect.

<Second Embodiment> A second embodiment of the present invention will be described with reference to the drawings. FIG. 3 is a schematic side sectional view of the ion feeding device according to the present embodiment. In FIG. 3, reference numeral 21 denotes at least a suction port 21a and a blowout port 2.
1b is a casing of the ion feeding device 11, and has a rectangular parallelepiped shape in which one end is opened as an outlet 21b and a plurality of suction ports 21b are provided in the circumferential direction of the side surface. Reference numeral 31 denotes a dielectric that is disposed substantially horizontally below the suction port 21a in the casing 2 and isolates first and second electrodes 41 and 51 described later, and is, for example, a flat plate type having a thickness of 1.3 mm. A Pyrex (R) glass plate can be preferably used.

A first electrode 41 is arranged below the dielectric 31 so as to partially contact the bottom surface 31a of the dielectric 31, and in the present embodiment, as an example thereof, a diameter of 1 m.
Needle-shaped having plate-shaped portions 41b made of stainless SUS304 in which five needle-shaped portions 41a formed in a needle-like shape having a length of m, a length of 20 mm and a tip curvature of 0.1 mm or less are provided in a row at intervals of 20 mm. It uses electrodes. The first electrode 41 is attached to the bottom surface in the casing 21 via the plate-shaped portion 41b so as to contact the bottom surface 31a of the dielectric 31 with the tip of the needle-shaped portion 41a. The first electrode 41 does not have to be needle-shaped, and may be linear or mesh-shaped. However, since the applied voltage required to effectively generate ions increases in the order of needle-shaped, linear, and mesh-shaped, it is ideal to use a needle-shaped electrode from the viewpoint of energy saving.

A second electrode 51 is disposed above the dielectric 31 so as to contact the upper surface 31b of the dielectric 31, and in the present embodiment, as an example, a wire diameter of 0.8 mm,
A mesh electrode made of stainless SUS304 having a mesh size of 9 mesh and a size of 30 mm × 150 mm is used. The second electrode 51 is in close contact with the upper surface 31b of the dielectric 31. Thereby, the pair of first and second electrodes 41, 51 are
As shown in the figure, they are opposed to each other with the dielectric 31 sandwiched therebetween.

The first AC power supply 61a arranged outside the casing 21 is connected to the first electrode 41 as a voltage application electrode and the second electrode 51 as a ground electrode, and the second electrode 51 is connected to the ground potential. As a result, a predetermined first AC voltage is applied between the first and second electrodes 41 and 51 from the first AC power supply 61a. And such a dielectric 3
1, first and second electrodes 41, 51 and first AC power supply 61a
Thus, the ion generator 111 referred to in the present embodiment is configured.

Further, above the suction port 21a in the casing 21, a third electrode 71 as an electric field applying means is provided as a second electrode.
It is arranged with a predetermined distance from the electrode 51. The third electrode 71 has, for example, a wire diameter of 0.8 mm and an opening number of 9
Mesh, stainless S with a size of 30 mm x 150 mm
A mesh electrode made of US304 can be used. Therefore, as shown in the figure, a positional relationship is established in which the suction port 21a is present on the side of the ion generator 111 with respect to the third electrode 71, and the air outlet 21b is present on the side opposite to the ion generator 111.

The second AC power supply 61b arranged outside the casing 21 is connected to the ground potential and the third electrode 71 is connected as a voltage applying electrode. The third AC power supply 61b is connected to the second AC power supply. A predetermined second AC voltage having a phase opposite to that of the first AC voltage is applied from 61b.

Next, an example of the operation of the ion feeding device 11 configured as above will be described. First AC power supply 61a
Using the second electrode 51 as a ground potential, a first AC voltage having an effective value of 1.5 kV and a frequency of 20 kHz is applied to the first electrode 41, and the third electrode 71 has a phase opposite to that of the first AC voltage. A second AC voltage having an effective value of 1.5 kV and a frequency of 20 kHz was applied.

As a result, discharge occurs on the surface of the dielectric 31 separating the first and second electrodes 41 and 51, and the first electrode 4
Each time the polarity of 1 is reversed, positive ions and negative ions are generated alternately, and an electric field whose polarity changes alternately is generated between the second and third electrodes 51, 71. At this time, since the first AC voltage and the second AC voltage are in opposite phases to each other, the third electrode 71 has a polarity opposite to the electric charge carried by the ions generated in the space by the operation of the ion generator 111. It will be. Therefore, both positive and negative ions are accelerated and quickly move to the third electrode 71 side. As a result, in the casing 21, from the suction port 21a to the outlet port 21b.
A flow of ions that escapes to the casing 21 occurs, and positive ions and negative ions are sent to the outside of the casing 21 from the air outlet 21b.

At this time, the concentrations of positive ions and negative ions sent out from the outlet 21b were measured by an air ion counter arranged at a position 10 cm away from the surface of the dielectric 31 in the direction of the outlet 21b. Ion concentration is 250,000 / cm ³ , negative ion concentration is 500,
5,000 / cm ³ and no voltage was applied to the third electrode 7 (both positive and negative ions 25,000 / cm 3
It was possible to raise the figure by an order of magnitude compared to ³ ).

Therefore, the ion feeding device 11 of the present embodiment
According to the method, ions can be sent by an electric field before the positive and negative ions generated in the space are neutralized and disappear. As a result, the positive and negative ions are attached to the surface of airborne bacteria and the bacteria can be efficiently sterilized and removed by the action of the active species generated by the chemical reaction. Further, since the negative ions can be blown in a rich state, the effect of relaxing the human mood can be obtained as a synergistic effect.

<Third Embodiment> A third embodiment of the present invention will be described with reference to the drawings. FIG. 4 is a schematic sectional view of the ion feeding device according to the present embodiment. In FIG. 4, 22 is at least a suction port 22a and a blowout port 22b.
And a casing of the ion feeding device 12 having, for example, a rectangular parallelepiped shape whose both ends are opened as a suction port 22a and a blowout port 22b. The space from the suction port 22a to the air outlet 22b inside the casing 22 is divided into a first space 22c and a second space 22d by a partition plate 32 made of a resin such as acrylic.

On the suction port 22a side in the first space 22c,
The first electrode 42 is provided. In the present embodiment, as an example, the diameter is 1 mm, the length is 20 mm, and the tip curvature is 0.1.
The three needle-shaped parts 42a formed in a needle shape of 20 mm or less are 20
Stainless steel SUS304 protruding in a line at a distance of mm
A needle-shaped electrode having a plate-shaped portion 42b made of metal is used, and the casing 22 is arranged so that the needle-shaped portion 42a faces the outlet 22b.
It is attached to the inner side surface via a plate-shaped portion 42b. still,
The first electrode 42 does not have to be needle-shaped, and may be linear or mesh-shaped. However, since the applied voltage required to effectively generate ions increases in the order of needle-shaped, linear, and mesh-shaped, it is ideal to use a needle-shaped electrode from the viewpoint of energy saving.

On the outlet 22b side in the first space 22c,
The second electrode 52 is provided. In the present embodiment, as an example thereof, a mesh electrode made of stainless SUS304 having a wire diameter of 0.8 mm, a mesh size of 9 mesh, and a size of 30 mm × 150 mm is used, and 10 mm from the tip of the needle-shaped portion 42 a of the first electrode 42. It is attached to the inner wall of the casing 22 so as to face the first electrode 42 with a space of.

In the first DC power source 92a arranged outside the casing 22, the positive electrode is connected to the first electrode 42 as the voltage applying electrode, and the negative electrode is connected to the second electrode 52 as the grounding electrode. 52 is the ground potential, and the first and second electrodes 4
A positive DC voltage is applied between the first and second DC power supplies 92a and 52. And such a first,
The second electrodes 42, 52 and the first DC power source 92a constitute the first ion feeding device 121 in the present embodiment.

On the other hand, the third electrode 72 is arranged on the suction port 22a side in the second space 22d. In the present embodiment, as an example thereof, three needle-shaped portions 72 formed in a needle shape having a diameter of 1 mm, a length of 20 mm, and a tip curvature of 0.1 mm or less.
Stainless steel SU in which a is projected in a line at intervals of 20 mm
A needle-shaped electrode having a plate-shaped portion 72b made of S304 is used, and the needle-shaped portion 72a is attached to the side surface inside the casing 22 via the plate-shaped portion 72b so as to face the outlet 72b side. The third electrode 72 does not have to be needle-shaped, and may be linear or mesh-shaped. However, since the applied voltage required to effectively generate ions increases in the order of needle-shaped, linear, and mesh-shaped, it is ideal to use a needle-shaped electrode from the viewpoint of energy saving.

On the air outlet 22b side in the second space 22d,
The fourth electrode 82 is provided. In the present embodiment, as an example thereof, a mesh electrode made of stainless SUS304 having a wire diameter of 0.8 mm, a mesh size of 9 mesh, and a size of 30 mm × 150 mm is used, and 10 mm from the tip of the needle-shaped portion 42a of the third electrode 72. It is mounted on the inner wall of the casing 22 so as to face the first electrode 72 with a space of.

In the second DC power source 92b arranged outside the casing 22, the negative electrode is connected to the third electrode 72 as the voltage applying electrode, and the positive electrode is connected to the fourth electrode 82 as the grounding electrode. 82 as the ground potential and the third and fourth electrodes 7
A negative DC voltage is applied between the first and second DC power supplies 92a and 82. And such a third,
The fourth electrodes 72, 82 and the second DC power source 92b constitute the second ion feeding device 122 referred to in the present embodiment.

Next, an example of the operation of the ion feeding device 12 configured as described above will be described. First, a positive DC voltage of +15 kV is applied to the first electrode 42 by using the first DC power supply 92a with the second electrode 52 as the ground potential.
A negative DC voltage of -15 kV was applied to the third electrode 72 by using the second DC power source 92b with the fourth electrode 82 set to the ground potential.

As a result, from the first electrode 42 to the first space 2
The positive charges move to the air molecules in 2c to generate positive ions, and the negative charges move to the air molecules in the second space 22d from the third electrode 72 to generate negative ions. A positive to negative electric field is generated between the electrodes 42 and 52,
An electric field from negative to positive is generated between the fourth electrodes 72 and 82. At this time, the second electrode 52 and the fourth electrode 82 have polarities opposite to the charges of positive or negative ions when they are generated in the space by the operation of the first ion sending device 121 and the second ion sending device 122. It will be. Therefore, the first space 22c
If the positive ions are accelerated inside, the ions move promptly to the second electrode 52 side, and at the same time, the negative ions accelerate to the fourth electrode 72 side accelerated in the second space 22d. This causes a flow of ions that escape from the suction port 22a to the air outlet 22b in the first space 22c and the second space 22d in the casing 22, mix positive ions and negative ions, and blow the air out of the casing 22 from the air outlet 22b. Sent to.

At this time, the concentrations of the positive ions and the negative ions sent from the air outlet 21b are changed from the dielectric 31 to the air outlet 2
The positive ion concentration was 30 when measured by an air ion counter placed at a distance of 10 cm in the 1b direction.
50,000 / cm ³ , negative ion concentration 300,000
It was pieces / cm ³ .

Next, a positive DC voltage of +10 kV is applied to the first electrode 42 by using the first DC power supply 92a with the second electrode 52 at the ground potential, and the fourth electrode 82 is used by using the second DC power supply 92b. To the third electrode 72 as a ground potential
A negative DC voltage of 15 kV was applied.

At this time, the concentrations of the positive ions and the negative ions sent from the air outlet 21b are changed from the dielectric 31 to the air outlet 2
The positive ion concentration was 20 when measured by an air ion counter arranged at a position 10 cm apart in the 1b direction.
50,000 / cm ³ , negative ion concentration 300,000
It was pieces / cm ³ .

Therefore, the ion feeding device 12 of the present embodiment
According to the method, ions can be sent by an electric field before the positive and negative ions generated in the space are neutralized and disappear. As a result, the positive and negative ions are attached to the surface of airborne bacteria, and the bacteria can be efficiently sterilized and removed by the action of the active species generated by the chemical reaction. Further, by adjusting the voltage applied to at least one of the first electrode 42 and the third electrode 72, the ratio of the positive / negative ions sent can be variously changed.

<Fourth Embodiment> A fourth embodiment of the present invention will be described with reference to the drawings. FIG. 5 is a schematic side sectional view of the air purifier according to the present embodiment. This air purifier is provided with the configuration of the ion feeding device (see FIG. 1) according to the first embodiment. In FIG. 5, members common to those of the ion feeding device shown in FIG.

As shown in FIG. 5, below the casing 14 of the air cleaner 13, a slit-shaped air suction port 14 is provided.
The opening a is formed. Further, the top plate of the casing 14 is also formed with a slit-shaped air outlet 14b. Reference numeral 15 is a dust filter mounted from the inside of the casing 14 to the suction port 14a. Reference numeral 16 is a deodorizing filter mounted in the air flow passage between the fourth electrode 8 and the ion generator.

Next, an example of the operation of the air purifier 13 configured as above will be described. The AC electrode 6 is used to set the second electrode 5 to the ground potential, and the effective value 1.
An AC voltage of 5 kV and a frequency of 20 kHz was applied, and a DC power supply 9 was used to apply a DC voltage of -15 kV to the third electrode 7 with the fourth electrode 8 at the ground potential.

As a result, electric discharge occurs on the surface of the dielectric 3 separating the first and second electrodes 4 and 5 to generate positive ions and negative ions, and an electric field is generated between the third and fourth electrodes 7 and 8. Occurs, electrons move from the tip of the needle-shaped portion 7a to air molecules, and the air molecules are negatively charged. This causes the charged air molecules to move toward the fourth electrode 8 side, which is at a relatively positive potential, while being accelerated. Therefore, the casing 14
A flow of air occurs inside, and the suction port 14a through the blowout port 14
There is a wind that escapes to b. By riding on this wind, positive ions and negative ions generated in the space by the operation of the ion generator are sent to the outside of the casing 14 from the air outlet 14b.

At this time, the concentrations of the positive ions and the negative ions sent from the air outlet 14b are changed to 10c from the air outlet 14b.
When measured by an air ion counter arranged at a position separated by m, the positive ion concentration is 150,000 / c
The m ³ and negative ion concentration were 150,000 / cm ³ .

In order to evaluate the sterilization performance of the air purifier 13, the air purifier 13 is set to a length of 2 m and a width of 2.5 m.
× Installed in the target area of 2.7m in height, sprayed E. coli in a mist form, started the operation of the air cleaner 13, and changed the number of E. coli in the target area with the passage of time.
n Tracking with an RCS air sampler showed that the number of bacteria decreased by 51% after running for about 1 hour. Therefore, by operating the air purifier 13 equipped with the ion feeding device according to the present invention,
Airborne bacteria can be sterilized and removed appropriately.

<Fifth Embodiment> A fifth embodiment of the present invention will be described with reference to the drawings. FIG. 6 is a schematic side sectional view of the air conditioner according to the present embodiment. This air cleaner is provided with the configuration of the ion feeding device 1 (see FIG. 1) according to the first embodiment. In FIG. 6, members common to those of the ion feeding device shown in FIG.

As shown in FIG. 6, slit-like air suction ports 24a are formed in the front and top surfaces of the casing 24 of the air conditioner 23. Also, casing 2
A louver 25 for adjusting the wind direction is provided below the suction port 24a of No. 4
And an air outlet 24b having air is formed. Reference numeral 26 denotes a dust filter mounted inside the casing 24 at the suction port 24a. 27 is a heat exchanger and 28 is a fan.

Next, an example of the operation of the air conditioner 23 configured as above will be described. AC power supply 6 (Fig. 1
(See FIG. 1), the second electrode 5 (see FIG. 1) is used as a ground potential, and an AC voltage having an effective value of 1.5 kV and a frequency of 20 kHz is applied to the first electrode 4 (see FIG. 1).
A DC voltage of −15 kV was applied to the third electrode 7 (see FIG. 1) using the fourth electrode 8 (see FIG. 1) as a ground potential by using (see FIG. 1). At the same time, the fan 28 was rotated to start the operation of the air conditioner 23.

As a result, the first and second electrodes 4 and 5 (see FIG.
Discharge is generated on the surface of the dielectric 3 which is separated from the reference electrode), positive ions and negative ions are generated, and an electric field is generated between the third and fourth electrodes 7 and 8 to generate air molecules from the tip of the needle portion 7a. The electrons move and the air molecules are negatively charged. This causes the charged air molecules to move toward the fourth electrode 8 side, which is at a relatively positive potential, while being accelerated. Therefore,
Air flow occurs in the casing 24, and the suction port 24a
A wind is emitted from the air outlet 24b to the air outlet 24b.

The outside air is sucked into the casing 24 from the suction port 24a by the rotation of the fan 28, is heat-exchanged when passing through the heat exchanger 27, and then is blown to the louver 25 from the air outlet 24b. It is adjusted and blown out. The positive ions and negative ions are also sent to the outside of the casing 24 from the air outlet 24b by this wind.

At this time, the concentrations of the positive ions and the negative ions sent from the outlet 24b are changed from the outlet 24b to 10c.
When measured by an air ion counter arranged at a position separated by m, the positive ion concentration is 150,000 / c
The m ³ and negative ion concentration were 150,000 / cm ³ .

In order to evaluate the sterilization performance of the air conditioner 23, the air conditioner 23 is set to a length of 2 m and a width of 2.5 m.
× Installed in a target area of 2.7 m in height, spraying E. coli in a mist form, starting the operation of the air conditioner 23, and changing the number of E. coli in the target area with the passage of time, Biotest Hyto
n Tracking with an RCS air sampler showed that the number of bacteria decreased by 51% after running for about 1 hour. Therefore, by operating the air conditioner 23 equipped with the ion feeding device 1 according to the present invention, airborne bacteria in the air can be appropriately disinfected.

According to the present embodiment, even when the rotation of the fan 28 is stopped, it is possible to blow positive and negative ions by operating only the ion feeding device 1.
In this case, the bactericidal removal effect of airborne bacteria can be obtained for energy saving.

The space sterilizing apparatus in which the ion feeding device according to the present invention is mounted is not limited to the above air purifier or air conditioner. In addition, for example, by mounting it on a dehumidifier, a humidifier, a refrigerator, an electric fan heater, an oil fan heater, a gas fan heater, an electric stove, or the like, it is possible to provide a space sterilizing apparatus that can obtain a similar air purification function.

[0073]

As described above, according to the ion feeding device of the present invention, positive ions and negative ions generated in the space by the operation of the ion generating device can be sent to a distance before being neutralized and disappeared. It is possible to secure a stable supply of positive ions and negative ions.

Devices such as an air cleaner and an air conditioner having such an ion feeding device function as a space sterilizing device and send positive and negative ions to the living space to suspend airborne bacteria in the air. The airborne bacteria in the air can be efficiently sterilized and removed by the active species generated by binding at the surface of the and reacting with them.

[Brief description of drawings]

FIG. 1 is a schematic side cross-sectional view of an ion delivery device according to a first embodiment of the present invention.

FIG. 2 is a perspective view showing a fragment of an ion generating portion of the ion feeding device.

FIG. 3 is a schematic perspective side sectional view of an ion feeding device according to a second embodiment of the present invention.

FIG. 4 is a schematic perspective side sectional view of an ion feeding device according to a third embodiment of the present invention.

FIG. 5 is a schematic perspective side sectional view of an air purifier according to a fourth embodiment of the present invention.

FIG. 6 is a schematic perspective side sectional view of an air conditioner according to a fifth embodiment of the present invention.

[Explanation of symbols] 1,11,12 Ion feeder 101,111 Ion generator 121 First ion feeder 122 Second Ion Feeder 2,21,22,14,24 Casing 3,31 Dielectric 32 partition boards 4,41,42 1st electrode 5,51,52 Second electrode 6 AC power supply 61a 1st AC power supply 61b Second AC power supply 7,71,72 Third electrode 8, 81, 82 4th electrode 9 DC power supply 92a First DC power supply 92b Second DC power supply 13 Air purifier 23 Air conditioner 28 fans

Continued front page    F-term (reference) 3L051 BC10                 4C080 AA07 AA09 BB05 HH02 JJ09                       KK02 LL02 MM01 QQ11

Claims (12)

[Claims] 1. A wind generated by providing an ion generator for generating positive ions and negative ions, and an electric field applying means for generating a positive or negative electric field in the space, and generating an electric field in the space by the electric field applying means. According to the present invention, the positive ion and negative ions are sent. 2. The electric field applying means comprises a pair of electrodes, one of which is a voltage applying electrode and the other of which is a grounding electrode, and the grounding electrode is arranged on the side of the ion generator. The ion feeder according to claim 1. 3. The ion feeder according to claim 2, wherein the grounding electrode is a mesh electrode having a mesh size of 9 to 24 mesh. 4. The voltage applied to the voltage applying electrode is
The ion feeding device according to claim 2 or 3, wherein the ion feeding device has a negative DC voltage. 5. An ion generator having a casing having at least an inlet and an outlet, and generating positive ions and negative ions, and a pair of electrodes, one of which is a voltage applying electrode and the other of which is a grounding electrode. An electric field applying means having the grounding electrode arranged on the side of the ion generator, the electric field applying means being provided in a space inside the casing that communicates the suction port and the air outlet, and the voltage applying electrode by the electric field applying means. An ion sending device, wherein the positive ions and the negative ions are sent by wind generated by generating an electric field between the ground electrode and the ground electrode. 6. The ion feeding device according to claim 5, wherein the electric field applying unit is applied with an electric field having a polarity opposite to that of the ions generated by the ion generating device. 7. A first electrode and a second electrode which face each other with an insulator interposed therebetween, and a third electrode which faces the second electrode and is separated by a predetermined distance and faces the second electrode, and the second electrode is grounded. And a second AC voltage applying means connected to the first electrode and applying an AC voltage to the first electrode, and a second electrode connected to the third electrode and applying an AC voltage to the third electrode. AC voltage applying means, wherein the phase of the AC voltage applied to the first electrode by the first AC voltage applying means and the AC voltage applied to the third electrode by the second AC voltage applying means An ion feeding device having a configuration in which the phase is reversed. 8. A casing having at least a suction port and a blowout port, the first and second electrodes facing each other with an insulator interposed therebetween, and the first electrode and the second electrode facing each other separated by a predetermined distance from the second electrode. A third electrode,
The first electrode is connected as a voltage applying electrode and the second electrode is connected as a grounding electrode, and is connected to a ground potential and a first AC voltage applying means for applying a first AC voltage to the first electrode. At the same time, the third electrode is connected as a voltage applying electrode, and second AC voltage applying means for applying a second AC voltage to the third electrode is provided inside the casing, and the suction port and the blower are provided. A positive ion and a negative ion are delivered from the outlet by providing a space inside the casing that communicates with an outlet and applying the phases of the first AC voltage and the second AC voltage as opposite phases. An ion feeding device having a mechanism for 9. A first electrode to which a voltage is applied, and the first electrode.
A first electrode comprising a second electrode, which is a ground electrode facing the electrode
Of the ion feed device, a third electrode to which a voltage having a polarity opposite to that of the voltage applied to the first electrode is applied, and a fourth electrode which is a grounding electrode facing the third electrode. 2 ion feeding devices, and the ion feeding device is configured to mix and send the ions fed from the first ion feeding device and the ions fed from the second ion feeding device. Ion feeder. 10. A casing having at least a suction port and a blowout port, a first electrode to which a positive DC voltage is applied, and a second electrode which is a grounding electrode provided opposite to the first electrode. The first ion feeding device is a third electrode which is insulated from the first ion feeding device and to which a negative DC voltage is applied, and a grounding electrode which is provided so as to face the third electrode. An ion feeding device comprising a second ion feeding device composed of a fourth electrode, and a configuration that is arranged in a space inside the casing that communicates the suction port and the air outlet. 11. The ion feeder according to claim 9, wherein the voltage applied to at least one of the first electrode and the third electrode is adjustable. 12. A bacterium in the space having the structure according to any one of claims 1 to 11, which is generated by the action of active species generated when positive ions and negative ions are bound on the surface of the bacterium. A space sterilizer characterized by sterilization.