JP2014018703A - Electric field generating device - Google Patents

Abstract

An electric field generating apparatus capable of generating a strong electric field and efficiently guiding a processing target to a region where the strong electric field is generated is provided.
An electrode 11a of a first electrode structure 10 has a larger electric field generation area than a core electrode 21 of a second electrode structure 20, thereby generating a strong unequal electric field between the electrodes. Furthermore, since the first electrode structure 10 and the second electrode structure 20 are arranged in this order from the upstream side to the downstream side of the fluid passage to be processed by providing a passage through which the fluid can pass, An unequal electric field is formed in the fluid passage. Accordingly, the sterilization apparatus 100 has a high processing capability because the processing object that has passed through the first electrode structure 10 is efficiently induced to an unequal electric field and further exposed to a strong electric field when reaching the second electrode structure 20. You can enjoy it. This function is applied to sterilizers, gas decomposers, and gas detector devices.
[Selection] Figure 2

Description

  The present invention relates to an apparatus for generating an unequal electric field.

It is known to process materials using an electric field. For example, Patent Document 1 discloses the use of an electric field for differentiation activity analysis, Patent Document 2 for cell separation, and Patent Document 3 for particle separation. In addition, it is also known to use an electric field for sterilization.
Conventionally, plasma sterilization method, electric discharge sterilization method, and ultraviolet ray sterilization method have been used as the sterilization method in the atmosphere of the medical field and food production field where aseptic environment is required, and the sterilization of viruses, pollen and bacteria in the home air. It was used.
However, plasma sterilization and electric discharge sterilization have a risk of electric shock, harm to humans due to generation of ozone, and a problem that a large-scale apparatus requires a high output power source. Further, in the ultraviolet sterilization, there is a problem that the use conditions are limited because the attenuation is large depending on the distance from the ultraviolet rays and the strength changes depending on the temperature.
Therefore, the present inventor has proposed an apparatus capable of sterilizing bacteria in the air using an electric field with a simple configuration in Patent Document 4.

JP 2009-291095 A JP 2010-22216 A JP 2010-253140 A JP 2008-154705 A

However, although the apparatus proposed in Patent Document 4 has a considerable sterilizing ability, an apparatus having a higher sterilizing ability is required depending on the environment used. In order to obtain a high sterilization capability, it is required that the electric field generator that is the basis of the sterilizer generates a strong electric field. And the apparatus which generate | occur | produces this strong electric field can be used for various uses including the example currently disclosed by patent document 1-patent document 3 not only in disinfection.
On the other hand, high sterilization ability is not always obtained simply by generating a strong electric field. When the treatment target is air containing bacteria, for example, it is desired to efficiently guide air to a region where a strong electric field is generated.
Therefore, an object of the present invention is to provide an electric field generator that can generate a strong electric field and efficiently guide a processing target to a region where the strong electric field is generated.

The present invention utilizes an unequal electric field to generate a strong electric field. In addition, in order to efficiently guide the processing target to the region where the strong electric field is generated, a passage through which the fluid (gas, liquid) to be processed flows is provided, and an element for generating an unequal electric field in this passage is provided. Suggest to arrange.
That is, the electric field generator of the present invention includes a passage through which fluid flows from upstream to downstream, a first electrode provided on the upstream side of the passage and configured to allow fluid to pass through, and downstream of the passage from the first electrode. And a second electrode whose tip is opposed to the first electrode and covered with a mask made of a dielectric.
In the present invention, since the first electrode has a larger electric field generation area than the second electrode, an unequal electric field is generated between the first electrode and the second electrode. Incidentally, a strong electric field is generated on the second electrode side.

  The electric field generator of the present invention that generates an unequal electric field can generate a strong electric field on the second electrode side having a small electric field generation area. Moreover, the present invention configures the first electrode so that the fluid can pass through, and the first electrode and the second electrode are arranged in this order from the upstream side to the downstream side of the fluid passage to be processed. An unequal electric field is formed in the fluid passage. Therefore, according to the electric field generator of the present invention, the processing object that has passed through the first electrode is efficiently induced to an unequal electric field, and further exposed to a strong electric field when reaching the second electrode, so that high processing capability can be enjoyed. .

  The electric field generation device of the present invention can include one or a plurality of electric field generation units each including a passage, a first electrode, and a second electrode. When a plurality of electric field generating units are provided, it is preferable to arrange the electric field generating units in a lattice shape in a direction orthogonal to the passage. By doing so, a large amount of objects to be processed can be processed without difficulty, and each electric field generating unit can be processed equally.

The present invention proposes a specific configuration in which a plurality of electric field generating units are arranged in a grid pattern.
The proposal includes a first electrode structure and a second electrode structure.
The first electrode structure includes an electrode material made of a metal mesh, an insulator plate in which first through holes penetrating the front and back are formed in a lattice shape, and laminated with the electrode material on the side facing the second electrode, . This 1st electrode structure is an electrode raw material, Comprising: The area | region enclosed by the 1st through-hole comprises a 1st electrode.
In the second electrode structure, a plurality of needle-like electrodes arranged along the passage form the second electrode, and a second through hole penetrating the front and back is formed in a lattice shape, on the side facing the first electrode A dielectric plate is in contact with the tip of the needle electrode. The second electrode structure is disposed such that each core electrode faces the first through hole of the corresponding insulator plate.
According to the above configuration, the electrode material of the first electrode structure is a metal mesh, and the portion to be the mask of the second electrode structure is a dielectric plate. Costs can be reduced compared to manufacturing units individually.
Furthermore, in the second electrode structure, if the core electrode is embedded in the dielectric plate from the tip thereof to a predetermined range and is held on the dielectric plate, the other member made of an insulator that holds the core electrode Can be omitted.

  In the present invention, a power source for applying a voltage between the first electrode and the second electrode can be provided as a component of the apparatus, and the power source can be obtained externally. In any case, when the first electrode is connected to the negative electrode side of the power source and the second electrode is connected to the positive electrode side of the power source, the treatment target, for example, bacteria can be induced to the second electrode side by Coulomb force.

  According to the electric field generator of the present invention, the processing object that has passed through the first electrode is efficiently induced to an unequal electric field, and further exposed to a strong electric field when reaching the second electrode, so that high processing capability can be enjoyed.

It is the schematic showing arrangement | positioning of the components which form the electric field in this Embodiment. It is a side view of the electric field sterilizer in this Embodiment. The formation of a strong electric field part that causes dielectric breakdown between electrodes is shown. The trajectory of the bacteria in an unequal electric field is shown. It shows self-destruction of bacteria by dielectric breakdown discharge of cell membrane.

Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.
In the present embodiment, an example in which the unequal electric field generator of the present invention is used in the sterilizer 100 is shown. As shown in FIGS. 1 and 2, the sterilizer 100 includes a first electrode structure 10, a second electrode structure 20 that is disposed to face the first electrode structure 10 at a predetermined interval, and wiring. A power source 30 that applies a voltage to the first electrode structure 10 and the second electrode structure 20 via 31 is provided as a main component. The sterilizer 100 generates an unequal high electric field between the first electrode structure 10 and the second electrode structure 20, thereby killing bacteria in the air.
Hereinafter, each component will be described in order.

[First electrode structure 10]
The first electrode structure 10, together with the second electrode structure 20, generates a plurality of unequal electric fields arranged in a lattice pattern in the planar direction.
As shown in FIG.1 and FIG.2, the 1st electrode structure 10 is comprised from the electrode raw material 11 and the insulator masks 12 and 13 which pinch | interpose the front and back both sides.

When a voltage is applied from the power supply 30, the electrode material 11 serves as a negative electrode and an electric field generation source.
In the present embodiment, the electrode material 11 is composed of a mesh (wire net) produced by knitting fine wires made of stainless steel. As the mesh opening, for example, a mesh of 160 mesh / inch can be used. The reason why the stainless steel mesh is used for the electrode material 11 is that corrosion resistance is taken into consideration. The same applies to the core electrode 21 of the second electrode structure 20.
The reason why the mesh is used for the electrode material 11 in this embodiment is to allow the air to be sterilized to pass through the front and back of the electrode material 11, and the electrode material 11 has a large number of air holes. become. Therefore, the electrode material 11 is not limited to a stainless steel mesh, and various members having a large number of air holes and having conductivity can be used. For example, a stainless steel plate with minute through holes formed by etching can be used for the electrode material 11, and a carbon film formed on a flat insulator surface can be used for the electrode material 11. In the latter case, the insulator corresponds to an insulator mask 13 to be described later, and a ventilation hole is formed through the insulator and the carbon film. However, it is advantageous in terms of cost to use a stainless steel mesh as in this embodiment.

The insulating mask 13 made of an insulating material has ventilation holes 13a penetrating the front and back surfaces thereof arranged in a lattice pattern. Each vent hole 13a of the present embodiment, the opening shape are circular, the opening area thereof as S _0. However, the opening shape of the vent hole 13a is not limited to a circle, and an ellipse, a polygon, and other shapes can be adopted. The number of the vent holes 13a is arbitrary, and can be appropriately changed depending on the size of the device and the purpose of use of the device. The insulator mask 13 is disposed on the side facing the second electrode structure 20.
Since the insulator mask 13 includes the vent hole 13a, the electrode material 11 laminated with the insulator mask 13 has a region corresponding to the vent hole 13a exposed to the second electrode structure 20, and has an area S _0. The electrode 11a (first electrode) is formed according to the number of the vent holes 13a. In this way, the insulator mask 13 creates the electrode 11a by covering the electrode material 11 with portions other than the vent holes 13a. In the electrode material 11, a portion of the electrode 11a facing the second electrode structure 20 becomes an electric field generating surface that actually generates an electric field.
Since the insulator mask 13 also plays a role of holding the electrode material 11, the insulator mask 13 is required to have insulating properties and a predetermined rigidity. As long as it has this function, the material which comprises the insulator mask 13 is not ask | required. Typically, an insulating resin such as bakelite (phenolic resin) can be used. When using a bakelite, if the thickness is about 1 mm, the desired rigidity can be easily obtained.
The area (diameter) of the air holes 13 a formed in the insulator mask 13 affects the intensity of the unequal electric field generated together with the second electrode structure 20. Although this point will be described in detail later, the vent hole 13a of the present embodiment is 2.25πmm ² (r = 1.5 mm, D = 3 mm).
In the present embodiment, the insulator mask 13 has the same plane area as that of the electrode material 11, but this is only an example. In this embodiment, the insulator mask 13 is shown as being integrally molded, but may be divided into a plurality of parts as long as it has a necessary function.

The insulator mask 12 of this embodiment has the same specifications as the insulator mask 13 including its material and vent holes 12a, and is disposed on the opposite side of the insulator mask 13 with the electrode material 11 in between. The insulator mask 12 is arranged so that the center of the vent hole 12a and the vent hole 13a of the insulator mask 13 coincide.
The insulator mask 12 is used to fix the electrode material 11 together with the insulator mask 13, and if the electrode material 11 can be fixed only by the insulator mask 13, the insulator mask 12 can be omitted. An alternative means for fixing the electrode material 11 can also be used.
The first electrode structure 10 obtained by laminating the insulator mask 12, the electrode material 11, and the insulator mask 13 has a vent 12 a, a mesh of the electrode material 11 (electrode 11 a), and a vent of the insulator mask 13. Since 13a communicates in the thickness direction, air can pass through the front and back.

[Second electrode part]
The second electrode structure 20, together with the first electrode structure 10, generates a plurality of unequal electric fields arranged in a grid pattern in the plane direction.
The second electrode structure 20 includes a plurality of core electrodes 21 (second electrodes), a holding block 22 that holds and fixes the core electrodes 21, and a dielectric mask 23 that covers the distal end surface of the core electrodes 21. Is composed of. The dielectric mask 23 is disposed so as to face the first electrode structure 10, and the holding block 22 is disposed behind the dielectric mask 23.

When a voltage is applied from the power source 30, the core electrode 21 serves as a positive electrode and an electric field generation source.
The core electrode 21 is held by the holding block 22 so as to be along the flow direction y of the air to be processed. The core electrode 21 is held by the holding block 22 so that the tip end surface thereof is flush with the surface of the holding block 22 (the surface facing the second electrode structure 20). Further, the core electrode 21 is held by the holding block 22 so that the tip surface thereof coincides with the center of the vent hole 13a. Therefore, the number of core electrodes 21 is the same as the number of vent holes 13 a formed in the insulator mask 13.
Adjacent core electrodes 21 are connected by electric wires 24 at the rear ends, and one of the core electrodes 21 arranged on the outermost periphery is connected to the power source 30 via the wiring 31. Current can be passed from the power supply 30 to all the core electrodes 21 via the core electrodes 21 so that they can act as electrodes without leakage.

The core electrode 21 of the present embodiment is made of stainless steel having a diameter of 0.4 mm and a length of 15 mm, and has a flat end surface. The area S ₁ of the tip surface of the core electrode 21 is 0.04πmm ² , which is much smaller than the area S ₀ (2.25πmm ² ) of the electrode 11a (S ₁ << S ₀ ).
The reason why stainless steel is used for the core electrode 21 and that other materials can be used is the same reason as the electrode material 11 of the first electrode structure 10. Therefore, for example, a member in which the surface of a needle-like insulator is coated with a conductive coating agent can be used as the core electrode.
Further, the shape of the tip of the core electrode 21 is not limited to a flat surface, but may be a circular arc surface or may be pointed, and the dimensions are not limited to the above.

The holding block 22 made of an insulating material is used for mechanically holding the core electrode 21, and holding holes 22 b matching the diameter of the core electrode 21 are formed in a lattice shape. The core electrode 21 is held by the holding block 22 by means such as adhesion or press fitting into the holding hole 22b.
The holding block 22 is formed with a circular vent hole 22a penetrating the front and back at the center of a region surrounded by the four core electrodes 21 adjacent to each other. The vent hole 22 a is disposed at a position corresponding to the electrode 11 a of the first electrode structure 10. The opening shape of the vent hole 22a is not limited to a circle.
The holding block 22 of this embodiment uses an acrylic plate having a plate thickness of 10 mm in which a vent hole 22a having a diameter of 5 mm is formed.

  The dielectric mask 23 made of a plate-like ferroelectric material is provided to prevent discharge from occurring between the needle tips of the electrode 11a and the core electrode 21. In addition, the dielectric mask 23 is provided with circular ventilation holes 23a penetrating the front and back in a lattice shape. The diameter of the vent hole 22a of the holding hole 22 of the vent hole 23a is the same, and the centers thereof coincide with each other. Further, the dielectric mask 23 generates an unequal electric field between the electric field generating surface 23b on the upper surface of the dielectric plate corresponding to the upper part of the core electrode 21 and the electrode 11a.

The dielectric mask 23 is disposed on the side facing the first electrode structure 10. In addition, the dielectric mask 23 contacts the surface side of the holding block 22 and is laminated. Therefore, the tip surface of the core electrode 21 is in contact with the back surface of the dielectric mask 23 (FIG. 2).
In the present embodiment, the dielectric mask 23 uses a flat plate made of barium titanate having a thickness of 1 mm and having a vent hole 23a having a diameter of 5 mm. The material and dimensions of the dielectric mask 23 and the shape of the vent hole 23a are not limited to the above, and can be changed as appropriate.

  In the second electrode structure 20 obtained by laminating the dielectric mask 23 and the holding block 22, the vent hole 23a of the dielectric mask 23 and the vent hole 22a of the holding block 22 communicate with each other in the thickness direction. Thus, the air to be processed can pass through the front and back.

[Assembly of first electrode structure 10 and second electrode structure 20]
The periphery of the first electrode structure 10 and the second electrode structure 20 described above is held by a rectangular frame 15. Accordingly, the dimensions in the planar direction of these components are the same. If the 1st electrode structure 10 and the 2nd electrode structure 20 are assembled | attached in this way, the electric field generation unit which consists of the electrode 11a and the core electrode 21 will be arrange | positioned at a grid | lattice form. In each electric field generating unit, the centers of the electrode 11a and the core electrode 21 coincide. Further, a filter 14 a and a filter 14 b are provided at the upper and lower opening ends of the frame 15. The filters 14 a and 14 b are provided to prevent foreign matters such as dust and water droplets contained in the air from flowing into the sterilizing apparatus 100 and to prevent the foreign substances that have flowed in from being discharged from the sterilizing apparatus 100. For the filters 14a and 14b, for example, the same stainless steel mesh as that used to form the electrode material 11 can be used.

[Power supply 30]
In the power supply 30, the end of the electrode material 11 and one of the core electrodes 21 are connected by a wiring 31. The power source 30 applies a voltage between the electrode material 11 and the core electrode 21 to generate an electric field. The power supply 30 can use a direct current, an alternating current, and a pulse current.

[Outline of sterilization treatment]
As described above, in the sterilization apparatus 100, the filter 14a, the first electrode structure 10, the second electrode structure 20, and the filter 14b are arranged in this order with a space therebetween (FIG. 2).
In the sterilizer 100, air to be processed flows from the filter 14a toward the filter 14b. Therefore, the filter 14a is located upstream and the filter 14b is located downstream.
The contaminated air containing the bacteria 40 flows into the sterilizer 100 along the direction y from the upstream. The inflowing air passes through the vent hole 12a, the electrode material 11 (electrode 11a) and the vent hole 13a of the first electrode structure 10, and an electric field generation region between the first electrode structure 10 and the second electrode structure 20 It flows into A and further flows toward the second electrode structure 20. That is, the sterilizer 100 includes a passage P through which air flows. The passage P continues to the surface of the dielectric mask 23, and the electrode 11a has a circular shape, and thus has a cylindrical shape. As will be described in detail later, an unequal electric field is formed inside the passage P, while the air that has passed through the electrode 11a flows into the passage P in which the unequal electric field is generated without leakage.

[Generation principle of unequal electric field]
Next, the principle of generation of an unequal electric field by the sterilization apparatus 100 having the above configuration will be described with reference to FIG.
When a voltage is applied between the power source 30 so that the electrode material 11 is a negative electrode and the core electrode 21 is a positive electrode, electric lines of force are emitted from the tip of the core electrode 21. The electric lines of force penetrate perpendicularly to the dielectric mask 23, and then pass through the electric field generating surface 23b of the dielectric mask 23 to spread radially in the electric field generating region A. The electric flux lines 41 advances toward the first electrode structure 10 and reaches the electrode 11a of the area S ₀ is a negative electrode, and an electric field generation surface 23b of the dielectric mask 23, and the electrodes 11a, non-uniform electric field between EF is generated (FIGS. 3A and 3B).
Here, the electrode 11 a has a larger area than the tip of the core electrode 21. Therefore, the density of the electric lines of force 41 is sparse on the electrode 11a side and dense on the core electrode 21 side (FIG. 3B), so that an unequal electric field EF can be generated. The unequal electric field EF has a characteristic that it is difficult to discharge compared to an equal electric field in which the density of electric lines of force between the electrodes is equal. This is due to the fact that the electric lines of force of the electrode 11a are sparse and current is difficult to flow. Therefore, the unequal electric field EF can prevent discharge and maintain the generated electric field.

  The combination of the core electrode 21 and the dielectric mask 23 is not limited to FIG. 3A. For example, as shown in FIG. 3C, the tip of the core electrode 21 is formed on the dielectric mask 23. It may be embedded. According to this embodiment, the holding block 22 can be omitted. Further, as shown in FIG. 3D, the dielectric mask 23 can be covered only on the tip surface of the core electrode 21. According to this embodiment, the usage amount of the dielectric mask 23 can be minimized.

[Field strength]
Next, the intensity of the electric field in the unequal electric field EF will be described with reference to FIG.
If the electric field (intensity) in the vicinity of the electrode 11a is E ₀ and the electric field of the electric field generating surface 23b is E ₁ , E ₀ and E ₁ are expressed by the equations (1) and (2). As described above, E ₁ >> E _{0 from} the relationship of S ₁ << S ₀ . That is, a strong electric field can be formed on the electric field generating surface 23b on the dielectric mask 23 by generating the unequal electric field EF.

The parameters in the equations (1) and (2) are as follows.
V _D : Applied voltage d ₀ : Distance between electrode material 11 and dielectric mask 23 surface, d ₁ : Thickness of dielectric mask 23 ε ₀ : Dielectric constant of electric field generation region A (space), ε ₁ : Dielectric mask Dielectric constant of 23

For example, setting the parameters below, the field generating surface 23b can form an extremely strong electric field E _1.
V _D = 5 kV, d ₀ = 1 mm, d ₁ = 1 mm
ε ₁ = 2920ε ₀ (barium titanate), S ₀ = 2.25πmm ² (D = 3 mm)
S ₁ = 0.04πmm ² (D = 0.4mm)
E ₁ = 2.8 × 10 ⁵ kV / m

[Induction and deposition of bacteria]
Next, a mechanism for sterilizing the bacteria 40 that have entered the unequal electric field EF will be described with reference to FIG.
The bacteria 40 are carried along the direction y by the air current, and sequentially pass through the vent hole 12a of the insulator mask 12, the electrode material 11 (electrode 11a), and the vent hole 13a of the insulator mask 13, and into the unequal electric field EF. Suppose you enter. In this process, the bacteria 40 that have passed through the electrode material 11 are polarized on the surface of the cell membrane by the electric field E ₀ (FIG. 5A). Specifically, positive charges are generated on the side close to the first electrode structure 10 (negative electrode), and negative charges are generated on the side close to the second electrode portion (positive electrode). As a result of this polarization, an induced voltage (Ve) is generated in the cell membrane of the bacterium 40. Bacteria 40 polarization charge occurs along the electric force lines 41 by a Coulomb force, while being directed towards the field generating surface 23b of the electric field E ₁ is generated, deposited thereon.
As described above, the sterilization apparatus 100 can induce and deposit the bacteria 40 locally by using the unequal electric field EF, and can give a strong electric field to the accumulated bacteria 40.

[Conditions for sterilization]
The following describes the conditions under which bacteria 40 deposited on the field generating surface 23b is (due to the destruction) killed by the electric field E ₁ to.
In the present embodiment, dielectric breakdown discharge is generated in the cell membrane to damage the cell membrane, and the cytoplasm in the cell is discharged, thereby killing the bacteria 40 (FIG. 5B). The bacterium 40 has a specific dielectric breakdown voltage Vs (≈1 V). When the above-described induced voltage (Ve) becomes larger than the dielectric breakdown voltage, a dielectric breakdown discharge occurs in the cell membrane.
The induced voltage Ve of the cell membrane is expressed by the following formula (3). In addition, the parameter of Formula (3) is as follows.
ε _e : Dielectric constant of cell membrane (protein) (2.5ε ₀ ) a: Film thickness of cell membrane (nm)

Here, with the electric field E ₁ (E ₁ = 2.8 × 10 ⁵ ) exemplified above, the induced voltage (Ve) of the cell membrane when the cell membrane thickness (a) is 10 nm is expressed by the following formula (4). Is required.
From the equation (4), the induced voltage (Ve) is 1.12 V, which is higher than the breakdown voltage (Vs≈1 V) of the bacteria 40. Therefore, the bacteria 40 can be killed. The induced voltage (Ve) generated in the cell membrane can be adjusted to an arbitrary value by appropriately changing various parameters of the formula (3), but can be sterilized with an applied voltage (V _D ) of about 5 kV.

As described above, according to the sterilization apparatus 100 of the present embodiment, the bacteria can be sufficiently killed even when the applied voltage is low, by using the unequal electric field EF even though the configuration is simple.
Moreover, according to the sterilization apparatus 100, since the bacteria are induced and deposited on the electric field generating surface 23b where a strong electric field is generated, the bacteria can be killed more reliably.
Moreover, according to the sterilization apparatus 100, since the electric field generation unit which consists of a pair of electrode 11a and the core electrode 21 is provided in matrix form, the area of the planar direction of the 1st electrode structure 10 and the 2nd electrode structure 20 By enlarging, a large amount of air containing the bacteria 40 can be sterilized without difficulty.

  Furthermore, according to the sterilization apparatus 100, since the unequal electric field EF is formed inside the passage P formed along the direction in which the air to be sterilized flows, the air is guided to the unequal electric field EF without leakage. As a result, an efficient sterilization treatment can be performed. In addition, since the electric field generating surface 23b that generates a strong electric field E1 is provided on the downstream side of the passage P, bacteria can be efficiently induced and deposited on the electric field generating surface 23b. In addition, since a plurality of such configurations are formed in a matrix shape, uniform sterilization is performed in the planar direction of the sterilization apparatus 100.

Although the sterilization apparatus 100 has been described as a preferred embodiment of the present invention, the present invention is characterized in that an unequal electric field EF is formed inside the passage P formed along the flow direction of the fluid to be sterilized. Other elements can be selected.
Moreover, when utilizing as the sterilizer 100, it is preferable to put the sterilizer 100 in the air flow path produced when the flow of the air to be sterilized is forcibly created. For example, the sterilizer 100 can be provided in the air flow path by providing the air blowing means, and the air flow path can be obtained by incorporating the sterilizer 100 in another device having the air blowing means, for example, an air conditioner. The sterilizer 100 can also be placed on the surface.

  Moreover, in this embodiment, although the example which utilized the nonuniform electric field for the apparatus which disinfects the microbe in air was shown, the nonuniform electric field apparatus proposed by this invention is used for other uses, for example, water, other fluids, etc. Can be used to sterilize bacteria and remove anaerobic substances.

  In addition to the above description, the configurations described in the above embodiments can be selected or changed to other configurations as appropriate without departing from the gist of the present invention.

100 Sterilizer 10 First electrode structure 11 Electrode material 11a Electrodes 12 and 13 Insulator masks 12a and 13a Vent holes 14a and 14b Filter 15 Frame 20 Second electrode structure 21 Core electrode 22 Holding block 22a Vent hole 22b Holding hole 23 Dielectric mask 23a Vent hole 23b Electric field generating surface 24 Electric wire 30 Power supply 31 Wiring 40 Bacteria 41 Electric field line P Passage EF Uneven electric field A Electric field generating region

Claims (5)

A passage through which fluid flows from upstream to downstream;
A first electrode provided upstream of the passage and through which the fluid can pass;
A second electrode provided on the downstream side of the passage with respect to the first electrode and having a tip facing the first electrode covered with a mask made of a dielectric, and the first electrode is the second electrode An electric field generating apparatus characterized in that an unequal electric field is generated between the first electrode and the second electrode by having a larger electric field generation area than the first electrode. An electric field generating unit comprising the passage, the first electrode, and the second electrode,
Arranged in a lattice pattern in a direction perpendicular to the passage,
The electric field generator according to claim 1. An electrode material made of metal mesh,
A first through-hole penetrating the front and back is formed in a lattice shape, and comprises an insulator plate laminated with the electrode material on the side facing the second electrode,
A first electrode structure in which the region surrounded by the first through hole is the first electrode structure, the electrode material;
A plurality of needle-like electrodes that form the second electrode and are disposed along the passage;
A second through-hole penetrating the front and back is formed in a lattice shape, and a dielectric plate is in contact with the tip of the needle electrode on the side facing the first electrode,
A second electrode structure in which each of the core electrodes is arranged to face the first through hole of the corresponding insulator plate;
Comprising
The electric field generator according to claim 2. In the second electrode structure,
The core electrode is held in the dielectric plate by being embedded in the dielectric plate from a tip thereof to a predetermined range.
The electric field generator according to claim 3. A power source for applying a voltage between the first electrode and the second electrode;
The first electrode is connected to the negative side of the power source and the second electrode is connected to the positive side of the power source;
The electric field generator as described in any one of Claims 1-4.