JP7494034B2 - Discharge Device - Google Patents

Description

The present invention relates to a discharge device.

The discharge device described in Patent Document 1 includes a housing, a substrate, a discharge generating unit, and insulating resin. The housing accommodates the substrate. One side of the housing is open. The discharge generating unit is disposed on the substrate. The discharge generating unit has a pair of needle electrodes. The pair of needle electrodes have a base end provided on the substrate and a tip end. The tip end protrudes from the insulating resin. The insulating resin covers the substrate and seals the opening.

JP 2017-162841 A

However, the ozone generator described in Patent Document 1 cannot prevent dust and other particles from accumulating between the electrodes. In other words, there is a possibility that dust and other particles may form a current leakage path. Therefore, it is difficult to prevent current leakage.

The present invention was made in consideration of the above problems, and aims to provide a discharge device that can suppress current leakage.

According to one aspect of the present invention, a discharge device includes a pair of electrodes, an electrode substrate, and a cover portion. The pair of electrodes discharge when a voltage is applied. The pair of electrodes are arranged on the electrode substrate. The cover portion faces the electrode substrate. A portion of each of the pair of electrodes penetrates the cover portion. There is no circuit substrate on which a circuit is formed between the electrode substrate and the cover portion.

According to another aspect of the present invention, the discharge device includes a pair of electrodes, an electrode substrate, and a cover portion. The pair of electrodes discharge when a voltage is applied to the pair of electrodes. The pair of electrodes are arranged on the electrode substrate. The cover portion faces the electrode substrate. The cover portion includes a main body portion and a pair of openings arranged in the main body portion. Each of the pair of electrodes is inserted into the pair of openings. The main body portion has an outer wall portion that surrounds the pair of electrodes. The outer wall portion faces the pair of electrodes in a direction that intersects with the direction in which the electrode substrate extends. There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion.

According to another aspect of the present invention, the discharge device includes an electrode, an electrode substrate, and a cover portion. The electrode discharges when a voltage is applied to the electrode. The electrode substrate has the electrode disposed thereon. The cover portion faces the electrode substrate. A portion of each of the electrodes penetrates the cover portion. There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion.

The discharge device of the present invention can suppress current leakage.

1 is a diagram showing a discharge device according to a first embodiment of the present invention; 2 is a cross-sectional view of the discharge device shown in FIG. 1 along II-II. FIG. 2 is a diagram showing a discharge device according to a first modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a second modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a third modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a fourth modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a fifth modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a sixth modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a seventh modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to an eighth modified example of the first embodiment. FIG. 13 is a diagram showing a discharge device according to a ninth modified example of the first embodiment.

Embodiments of the present invention will be described below with reference to the drawings. Note that in the drawings, the same or corresponding parts will be given the same reference symbols and descriptions will not be repeated.

[Embodiment 1]
A discharge device 100 according to a first embodiment of the present invention will be described with reference to Fig. 1 and Fig. 2. First, the discharge device 100 according to the first embodiment will be described with reference to Fig. 1. Fig. 1 is a diagram showing the discharge device 100 according to the first embodiment. The discharge device 100 generates active species by discharging. The active species includes ions.

The discharge device 100 has a plurality of electrodes 19, a housing section 1, and a cover section 2. The plurality of electrodes 19 discharge when a voltage is applied. The plurality of electrodes 19 is, for example, two electrodes 19. That is, the plurality of electrodes 19 is, for example, a pair of electrodes 19. A portion of each of the pair of electrodes 19 penetrates the cover section 2.

The pair of electrodes 19 are, for example, needle-shaped or brush-shaped electrodes. When a high voltage is applied to the pair of electrodes 19, a corona is generated. In other words, each of the pair of electrodes 19 discharges and generates ions.

For example, one of the pair of electrodes 19 emits positive ions when discharged. The positive ions are cluster ions (H ⁺ (H ₂ O) _m (m is any positive number equal to or greater than zero)) in which a plurality of water molecules are clustered around a hydrogen ion (H ⁺ ). Furthermore, for example, the other of the pair of electrodes 19 emits negative ions when discharged. The negative ions are cluster ions (O ₂ - (H ₂ O) _n (n is any positive number equal to or greater than zero)) in which a plurality of water molecules are clustered around an oxygen ion (O ₂ - ).

When emitting positive ions and negative ions, the greater the distance between the electrode 19 that emits positive ions and the electrode 19 that emits negative ions, the greater the amount of ions emitted from each electrode 19.

The released positive and negative ions surround, for example, mold spores floating in the air, and cause a chemical reaction on the surface of the mold spores. The chemical reaction produces active species, hydroxyl radicals (.OH). The action of the hydroxyl radicals (.OH) then removes the mold spores.

The housing 1 houses a part of the pair of electrodes 19. The housing 1 is a box-shaped housing. The housing 1 has insulating properties. The housing 1 is formed of, for example, resin.

The cover 2 covers the portion of the housing 1 where the pair of electrodes 19 are arranged. The cover 2 has insulating properties. The cover 2 is made of, for example, resin.

Next, the discharge device 100 will be described in detail with reference to FIG. 2. FIG. 2 is a cross-sectional view of the discharge device 100 shown in FIG. 1 taken along line II-II. As shown in FIG. 2, the discharge device 100 further includes an electrode substrate 5, a circuit substrate 6, an electronic component 7, a transformer 8, and an encapsulant 9.

As shown in FIG. 2, the storage unit 1 stores an electrode substrate 5, a circuit board 6, electronic components 7, a transformer 8, and an encapsulating material 9. The storage unit 1 is box-shaped with an opening 13. The storage unit 1 has a side wall portion 11 and a bottom wall portion 12.

The bottom wall portion 12 supports the side wall portion 11. The transformer 8 and electronic components 7 are arranged on the bottom wall portion 12. The side wall portion 11 surrounds the bottom wall portion 12. The side wall portion 11 extends from the bottom wall portion 12 toward the opening 13.

A pair of electrodes 19 is arranged on the electrode board 5. The electrode board 5 is electrically connected to the pair of electrodes 19. The electrode board 5 is a so-called printed circuit board. The electrode board 5 is arranged on the opening 13 side of the circuit board 6. The electrode board 5 is connected to the transformer 8 by lead wires.

A circuit is formed on the circuit board 6. Specifically, a circuit is formed on the circuit board 6 for electrically connecting with the electrode board 5, the transformer 8, and the electronic components 7. More specifically, the circuit board 6 is electrically connected with the electrode board 5, the transformer 8, and the electronic components 7 by lead wires. The circuit board 6 is disposed between the electronic components 7 and the electrode board 5.

The electronic components 7 include a power supply terminal, a diode, a resistor element, a transistor, a capacitor, etc. The power supply terminal is connected to an external power supply via a lead wire.

The transformer 8 boosts the voltage applied to the pair of electrodes 19.

The encapsulating material 9 is, for example, a urethane resin or an epoxy resin. The encapsulating material 9 hardens, for example, over time. Also, for example, the encapsulating material 9 hardens due to temperature (heat) or light (ultraviolet rays).

As shown in FIG. 2, the cover portion 2 faces the electrode substrate 5. Furthermore, the circuit substrate 6 is not present in the space A between the electrode substrate 5 and the cover portion 2. For example, dust can be prevented from accumulating between the electrode substrate 5 and the cover portion 2 and on the circuit substrate 6. Therefore, dust and the like can be prevented from accumulating between the electrodes 19. In other words, the formation of a current leak path can be prevented. A leak path refers to a path of leakage current that leaks into an insulated portion of an electronic circuit. As a result, it is possible to prevent unintended current leakage within the electric circuit due to dust and the like accumulated between the electrodes 19.

The cover part 2 covers the opening 13 of the storage part 1. The cover part 2 includes a main body part 21 and a pair of openings 20. A pair of electrodes 19 are inserted into each of the pair of openings 20.

The main body 21 faces the electrode substrate 5. Specifically, the main body 21 faces the electrode substrate 5 while being spaced apart from the electrode substrate 5.

The main body 21 has a wall 3 extending in a cross direction PD1 crossing the electrode substrate 5. The wall 3 is disposed between a pair of openings 20. In other words, the wall 3 is disposed between the electrodes 19. Thus, the distance along the surface of the main body 21 from electrode 19 to electrode 19 is increased by having the wall 3. Therefore, it takes a long time for a substance that reduces the insulating performance to adhere to the main body 21 and for a current leak path to be formed between electrodes 19. As a result, the time until the leak path is formed can be delayed. The wall 3 may be formed integrally with the main body 21. The wall 3 may also be attached to the main body 21 later.

The ions generated by the electrodes to which a high voltage is applied react with water molecules in the air, generating, for example, ammonium nitrate. Ammonium nitrate has water absorption properties. Ammonium nitrate may adhere to structures around the electrodes. Ammonium nitrate is highly water absorbent, so when it absorbs moisture in the air, the moisture conducts current. In other words, when ammonium nitrate adheres to a structure formed of an insulator, the insulating performance of the structure decreases. Furthermore, when ammonium nitrate further adheres to the structure between the electrodes, a current leakage path may be formed. When a current leakage path is formed, it becomes difficult for the discharge device to stably generate ions. However, in the discharge device 100 of this embodiment, since the wall portion 3 is formed in the main body portion 21, the distance along the surface of the main body portion 21 from electrode 19 to electrode 19 becomes long. Therefore, it takes a long time for a current leakage path to be formed. As a result, the period during which ions can be stably generated can be extended.

As shown in FIG. 2, the main body 21 further includes a flat plate portion 22. The flat plate portion 22 extends along an extension direction PD2. The extension direction PD2 indicates a direction along the electrode substrate 5. In other words, the flat plate portion 22 extends along the electrode substrate 5.

The wall portion 3 also includes a first wall portion 31. As shown in FIG. 2, the first wall portion 31 is disposed on the flat plate portion 22 and extends in a first direction D1. The first direction D1 indicates a direction from the electrode substrate 5 toward the flat plate portion 22. In other words, the distance along the surface of the main body portion 21 from electrode 19 to electrode 19 on the first direction D1 side is increased by having the first wall portion 31. Therefore, when a substance that reduces the insulating performance adheres to the main body portion 21, it is possible to delay the formation of a current leakage path between electrodes 19. As a result, it is possible to lengthen the period during which ions can be generated stably.

(First Modification)
Next, a first modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 3. The first modified example differs from the first embodiment mainly in the arrangement of the wall portion 3. The following describes the differences between the first modified example and this embodiment.

Figure 3 is a diagram showing a discharge device 100 according to a first modified example of the first embodiment. The wall portion 3 includes a second wall portion 32. The second wall portion 32 is disposed on the flat plate portion 22. As shown in Figure 3, the second wall portion 32 extends in the second direction D2. The second direction D2 indicates the direction from the flat plate portion 22 toward the electrode substrate 5. Therefore, the distance along the surface of the main body portion 21 from electrode 19 to electrode 19 on the second direction D2 side is increased by having the second wall portion 32. In other words, when a substance that reduces the insulating performance adheres to the main body portion 21, the formation of a current leakage path between electrodes 19 can be delayed. As a result, the period during which ions can be generated stably can be increased.

The second wall portion 32 of the first modified example extends from the flat plate portion 22 until it abuts against the electrode substrate 5. Therefore, the second wall portion 32 divides the space A into a space on one electrode 19 side and a space on the other electrode 19 side. As a result, the formation of a current leakage path between electrodes 19 in the space A between the cover portion 2 and the electrode substrate 5 can be suppressed.

(Second Modification)
Next, a second modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 4. The second modified example differs from the first embodiment mainly in the arrangement of the wall portion 3. The following describes the differences between the second modified example and the present embodiment.

Figure 4 is a diagram showing a discharge device 100 according to a second modified example of the first embodiment. As shown in Figure 4, the wall portion 3 of the main body portion 21 of the second modified example includes a pair of wall portions 3 extending toward the second direction D2. The pair of wall portions 3 includes a third wall portion 33 and a fourth wall portion 34.

The third wall portion 33 extends from the flat plate portion 22 in the second direction D2. The third wall portion 33 corresponds to an example of "one wall portion." The third wall portion 33 has an end portion 33A on the side of the first direction D1 and an end portion 33B on the side of the second direction D2.

The fourth wall portion 34 extends from the flat plate portion 22 in the second direction D2. The fourth wall portion 34 faces the third wall portion 33. The fourth wall portion 34 corresponds to an example of the "other wall portion." The fourth wall portion 34 has an end portion 34A on the side of the first direction D1 and an end portion 34B on the side of the second direction D2.

The flat plate portion 22 has a first flat plate portion 221, a second flat plate portion 222, and a third flat plate portion 223. The first flat plate portion 221 extends along the extension direction PD2. The first flat plate portion 221 is disposed on the third direction D3 side of the third wall portion 33. The third direction D3 indicates the direction from the fourth wall portion 34 toward the third wall portion 33.

The first flat plate portion 221 extends from one of the pair of openings 20 toward the end 33A of the third wall portion 33 on the first direction D1 side. Specifically, the first flat plate portion 221 extends from the opening 20 on the third direction D3 side to the end 33A of the third wall portion 33.

The second flat plate portion 222 extends along the extension direction PD2. The second flat plate portion 222 is disposed on the fourth direction D4 side of the fourth wall portion 34. The fourth direction D4 indicates the direction from the third wall portion 33 to the fourth wall portion 34.

The second flat portion 222 extends from the other of the pair of openings 20 toward the end 34A of the fourth wall portion 34 on the first direction D1 side. Specifically, the second flat portion 222 extends from the opening 20 on the fourth direction D4 side to the end 34A of the fourth wall portion 34.

The third flat plate portion 223 extends along the extension direction PD2. Specifically, the third flat plate portion 223 extends from the third wall portion 33 to the fourth wall portion 34. More specifically, the third flat plate portion 223 extends from the end portion 33B of the third wall portion 33 in the second direction D2 to the end portion 34B of the fourth wall portion 34 in the second direction D2.

That is, a recess is formed in the flat plate portion 22. The height of the first flat plate portion 221 in the cross direction PD1 is different from the height of the third flat plate portion 223 in the cross direction PD1. The height of the second flat plate portion 222 in the cross direction PD1 is different from the height of the third flat plate portion 223 in the cross direction PD1. Therefore, the distance from electrode 19 to electrode 19 along the surface of the main body portion 21 in the first direction D1 is long. Furthermore, the distance from electrode 19 to electrode 19 along the surface of the main body portion 21 in the second direction D2 is long. Therefore, when a substance that reduces the insulating performance adheres to the main body portion 21, the formation of a current leakage path between electrodes 19 and 19 can be delayed. As a result, the period during which ions can be generated stably can be extended.

(Third Modification)
Next, a third modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 5. The discharge device 100 of the third modified example differs from the first embodiment, the first modified example, and the second modified example mainly in the shape of the wall portion 3. Below, the differences between the discharge device 100 of the third modified example and the first, first modified example, and the second modified example will be described.

Figure 5 is a diagram showing a discharge device 100 according to a third modified example. As shown in Figure 5, the wall 3 of the main body 21 of the third modified example has a cylindrical shape. That is, the wall 3 includes a cylindrical fifth wall 35. Specifically, the wall 3 includes a pair of fifth wall portions 35. Each of the pair of fifth wall portions 35 surrounds the electrode 19. The pair of fifth wall portions 35 is, for example, cylindrical in shape.

The pair of fifth walls 35 extend along the intersecting direction PD1. Specifically, the fifth walls 35 extend in the first direction D1 and the second direction D2. In other words, the fifth walls 35 suppress adhesion of water-absorbent substances such as ammonium nitrate to the flat plate portion 22 and the electrode substrate 5. Therefore, the fifth walls 35 can suppress the formation of a current leak path in the electrode substrate 5. As a result, ions can be generated stably.

Each of the pair of fifth walls 35 has an end 35A on the first direction D1 side and an end 35B on the second direction D2 side. Specifically, the fifth wall 35 has a first opening 20A on the first direction D1 side. The fifth wall 35 also has a second opening 20B on the second direction D2 side. The second opening 20B faces the electrode substrate 5.

The flat plate portion 22 is disposed between the end portion 35A on the first direction D1 side and the end portion 35B on the second direction D2 side. In other words, the fifth wall portion 35 extends in the first direction D1 and the second direction D2.

(Fourth Modification)
Next, a fourth modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 6. The discharge device 100 of the fourth modified example differs from the first embodiment, the first modified example, the second modified example, and the third modified example mainly in the shape of the wall portion 3. Below, the differences between the discharge device 100 of the fourth modified example and the first modified example, the first modified example, the second modified example, and the third modified example will be described.

Figure 6 is a diagram showing a discharge device 100 according to a fourth modified example. As shown in Figure 6, the wall 3 of the main body 21 of the fourth modified example has a cylindrical shape. That is, the wall 3 includes a cylindrical sixth wall 36. Specifically, the wall 3 includes a pair of sixth wall portions 36. Each of the pair of sixth wall portions 36 surrounds the electrode 19. The pair of sixth wall portions 36 is, for example, cylindrical in shape.

The sixth wall portion 36 has an end portion 36A on the first direction D1 side and an end portion 36B on the second direction D2 side. Specifically, the sixth wall portion 36 has a first opening 20A on the first direction D1 side. The sixth wall portion 36 has a second opening 20B on the second direction D2 side. The second opening 20B faces the electrode substrate 5.

Furthermore, the inner diameter of the cylindrical shape of the sixth wall portion 36 increases toward the end portion 36A on the first direction D1 side of the electrode 19. Therefore, the distance between the electrode 19 and the sixth wall portion 36 increases, and dust can be prevented from becoming clogged between the electrode 19 and the sixth wall portion 36. As a result, dust between the electrode 19 and the sixth wall portion 36 can be prevented from becoming a leak path.

Specifically, as shown in FIG. 6, the inner diameter of the first opening 20A is an inner diameter LA. On the other hand, the inner diameter of the second opening 20B is an inner diameter LB. The inner diameter LA of the first opening 20A is larger than the inner diameter LB of the second opening 20B.

The sixth wall portion 36 may have an inner diameter that increases as the portion extending from the flat plate portion 22 in the first direction D1 moves from the flat plate portion 22 toward the first opening 20A. This increases the distance between the electrode 19 and the sixth wall portion 36, and prevents dust from clogging between the electrode 19 and the sixth wall portion 36. As a result, dust between the electrode 19 and the sixth wall portion 36 can be prevented from becoming a leak path. The inner diameter of the sixth wall portion 36 does not change in the portion extending from the flat plate portion 22 toward the second opening 20B.

(Fifth Modification)
Next, a fifth modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 7. The discharge device 100 of the fifth modified example mainly differs in that it has the first wall portion 31 of the first embodiment, the second wall portion 32 of the first modified example, the third wall portion 33 and the fourth wall portion 34 of the second modified example, the fifth wall portion 35 of the third modified example, and the sixth wall portion 36 of the fourth modified example. Below, the differences between the discharge device 100 of the fifth modified example and the first, second, third, and fourth modified examples will be described.

Figure 7 is a diagram showing a discharge device 100 according to a fifth modified example of the first embodiment. The cover portion 2 includes a main body portion 21 and a pair of openings 20. A pair of electrodes 19 are inserted into the pair of openings 20. The main body portion 21 has a plurality of walls 3 and a flat plate portion 22. The plurality of walls 3 include a first wall portion 31, a second wall portion 32, a third wall portion 33, a fourth wall portion 34, a fifth wall portion 35, and a sixth wall portion 36. The flat plate portion 22 includes a first flat plate portion 221, a second flat plate portion 222, and a third flat plate portion 223.

The first flat plate portion 221 of the fifth modified example extends from the sixth wall portion 36 to the third wall portion 33. Specifically, the first flat plate portion 221 extends from between the end 36A and the end 36B of the sixth wall portion 36 in the third direction D3 to the end 33A of the third wall portion 33.

The second flat plate portion 222 of the fifth modified example extends from the fifth wall portion 35 to the fourth wall portion 34. Specifically, the second flat plate portion 222 extends from between the end portion 35A and the end portion 35B of the fifth wall portion 35 in the fourth direction D4 to the end portion 34A of the fourth wall portion 34.

The third flat plate portion 223 of the fifth modified example extends from the third wall portion 33 to the fourth wall portion 34. Specifically, the third flat plate portion 223 extends from the end portion 33B of the third wall portion 33 in the second direction D2 to the end portion 34B of the fourth wall portion 34 in the second direction D2.

The first wall portion 31 of the fifth modified example is disposed on the second flat plate portion 222 and extends in the first direction D1. The first wall portion 31 is disposed between the fourth wall portion 34 and the fifth wall portion 35. Therefore, when a substance that reduces the insulating performance adheres to the second flat plate portion 222, it is possible to reduce the formation of a current leakage path between the electrode 19 on the fourth direction D4 side and the electrode 19 on the third direction D3 side. As a result, ions can be generated stably.

The second wall portion 32 of the fifth modified example is disposed on the third flat plate portion 223 and extends from the third flat plate portion 223 in the second direction D2. Specifically, the second wall portion 32 extends from the third flat plate portion 223 until it abuts the electrode substrate 5. Therefore, the second wall portion 32 divides the space A into a space on the third direction D3 side and a space on the fourth direction D4 side. As a result, in the space A between the cover portion 2 and the electrode substrate 5, the formation of a current leakage path between the electrode 19 in the third direction D3 to the electrode 19 in the fourth direction D4 can be suppressed.

The second wall portion 32 may extend from the end portion 33B of the third wall portion 33. That is, the second wall portion 32 is continuous with the third wall portion 33. In other words, the second wall portion 32 may be disposed at a position overlapping with the third wall portion 33 in the first direction D1. The second wall portion 32 may extend from the end portion 34B of the fourth wall portion 34. That is, the second wall portion 32 is continuous with the fourth wall portion 34. In other words, the second wall portion 32 may be disposed at a position overlapping with the fourth wall portion 34 in the first direction D1.

The third wall portion 33 of the fifth modified example extends from the flat plate portion 22 in the second direction D2. Specifically, the third wall portion 33 extends from the first flat plate portion 221 in the second direction D2. More specifically, the third wall portion 33 extends from the first flat plate portion 221 to the third flat plate portion 223.

The fourth wall portion 34 of the fifth modified example extends from the flat plate portion 22 in the second direction D2. The fourth wall portion 34 faces the third wall portion 33. Specifically, the fourth wall portion 34 extends from the second flat plate portion 222 in the second direction D2. More specifically, the fourth wall portion 34 extends from the second flat plate portion 222 to the third flat plate portion 223.

The third wall 33, the fourth wall 34, the first flat plate 221, the second flat plate 222, and the third flat plate 223 form a recess in the main body 21. That is, the distance along the surface of the main body 21 in the first direction D1 from the electrode 19 in the third direction D3 to the electrode 19 in the fourth direction D4 is longer. Furthermore, the distance along the surface of the main body 21 in the second direction D2 from the electrode 19 in the third direction D3 to the electrode 19 in the fourth direction D4 is longer. Therefore, when a substance that reduces the insulating performance adheres to the main body 21, the formation of a current leakage path between the electrode 19 in the third direction D3 and the electrode 19 in the fourth direction D4 can be delayed. As a result, the period during which ions can be generated stably can be extended.

The fifth wall portion 35 of the fifth modified example extends along the intersecting direction PD1. Specifically, the fifth wall portion 35 extends in the first direction D1 and the second direction D2. In other words, the fifth wall portion 35 suppresses adhesion of water-absorbent substances such as ammonium nitrate to the second flat plate portion 222 and the electrode substrate 5. Therefore, the fifth wall portion 35 can suppress the formation of a current leakage path in the cover portion 2 and the electrode substrate 5. As a result, ions can be generated stably.

The sixth wall portion 36 of the fifth modified example extends in the first direction D1 and the second direction D2. Specifically, the inner diameter of the cylindrical shape of the sixth wall portion 36 increases toward the end portion 36A on the first direction D1 side of the electrode 19. Therefore, the distance between the electrode 19 and the sixth wall portion 36 increases, and dust can be prevented from becoming clogged between the electrode 19 and the sixth wall portion 36. As a result, dust between the electrode 19 and the sixth wall portion 36 can be prevented from becoming a leak path.

The discharge device 100 of the fifth modified example has a first wall portion 31, a second wall portion 32, a third wall portion 33, a fourth wall portion 34, a fifth wall portion 35, and a sixth wall portion 36. Therefore, it is possible to suppress the formation of a current leakage path in the cover portion 2 and the electrode substrate 5, while delaying the formation of a current leakage path between electrodes 19. As a result, it is possible to extend the period during which ions can be generated more stably.

(Sixth Modification)
Next, a sixth modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 8. The discharge device 100 of the sixth modified example is mainly different in that it has an outer wall portion 37. Below, the differences between the discharge device 100 of the sixth modified example and the first, second, third, and fifth modified examples of the first embodiment will be described.

Figure 8 is a diagram showing a discharge device 100 of a sixth modified example. The cover part 2 of the sixth modified example includes a main body part 21 and a pair of openings 20. A pair of electrodes 19 are inserted into the pair of openings 20, respectively. The main body part 21 has an outer wall part 37 and a flat plate part 22.

The outer wall portion 37 surrounds the pair of electrodes 19. The outer wall portion 37 faces the electrodes 19 in a direction intersecting the direction in which the electrode substrate 5 extends. Therefore, when the discharge device 100 is attached to an apparatus, it prevents water-absorbent substances such as ammonium nitrate from adhering to the apparatus other than the discharge device 100. As a result, it is possible to prevent the formation of a leak path toward the circuit board of the apparatus to which the discharge device 100 is attached.

More specifically, the outer wall portion 37 extends in the first direction D1. The outer wall portion 37 is formed on the outside of the flat plate portion 22. In other words, the outer wall portion 37 is disposed between the flat plate portion 22 and the storage portion 1. Therefore, the outer wall portion 37 surrounds the flat plate portion 22.

(Seventh Modification)
Next, a seventh modification of the discharge device 100 of the first embodiment will be described with reference to Fig. 9. The discharge device 100 of the seventh modification is different from the first, first, second, third, fourth, fifth, and sixth modifications of the first embodiment mainly in the shape of the flat plate portion 22. Below, the differences between the discharge device 100 of the seventh modification and the first, second, third, fourth, fifth, and sixth modifications of the first embodiment will be described.

Figure 9 is a diagram showing a discharge device 100 of the seventh modified example. The discharge device 100 of the seventh modified example includes a plurality of electrodes 19, a storage section 1, and a cover section 2. The electrodes 19 discharge when a voltage is applied. The storage section 1 stores a portion of the pair of electrodes 19, an electrode board 5, a circuit board 6, an electronic component 7, a transformer 8, and an encapsulating material 9. The cover section 2 covers the portion of the storage section 1 where the pair of electrodes 19 are arranged.

The cover portion 2 includes a main body portion 21 and a pair of openings 20. A pair of electrodes 19 are inserted into each of the pair of openings 20.

The main body portion 21 faces the electrode substrate 5 while being spaced apart from the electrode substrate 5. The main body portion 21 has a flat plate portion 22. The flat plate portion 22 extends along the extension direction PD2.

The flat plate portion 22 has a wave shape. Specifically, the wave shape of the flat plate portion 22 is disposed in a portion of the flat plate portion 22 between a pair of openings 20. In other words, the distance along the surface of the flat plate portion 22 from one opening 20 to the other opening 20 is longer than in a flat plate portion that is not wave-shaped. Therefore, it takes time for a leak path to form. Therefore, it is possible to delay the formation of a current leak path between electrodes 19. As a result, the period during which ions can be generated stably can be extended.

(Eighth Modification)
Next, an eighth modified example of the discharge device 100 of the first embodiment will be described with reference to Fig. 10. The discharge device 100 of the eighth modified example differs from the first, first, second, third, fourth, fifth, sixth, and seventh modified examples mainly in the shape of the wall portion 3. Below, the differences between the discharge device 100 of the eighth modified example and the first, second, third, fourth, fifth, sixth, and seventh modified examples of the first embodiment will be described.

Figure 10 is a diagram showing a discharge device 100 according to an eighth modified example. As shown in Figure 8, the wall 3 of the main body 21 of the eighth modified example has a cylindrical shape. That is, the wall 3 includes a cylindrical seventh wall 38. Specifically, the wall 3 includes a pair of seventh wall portions 38. Each of the pair of seventh wall portions 38 surrounds the electrode 19. The pair of seventh wall portions 38 is, for example, cylindrical in shape.

The pair of seventh wall portions 38 extend along the intersecting direction PD1. Specifically, the seventh wall portions 38 extend in the first direction D1. More specifically, the seventh wall portions 38 extend from the flat plate portion 22 in the first direction D1. In other words, the wall portions 3 are not disposed in the space A between the cover portion 2 and the electrode substrate 5. In other words, the seventh wall portions 38 suppress adhesion of water-absorbent substances such as ammonium nitrate to the flat plate portion 22. Therefore, the seventh wall portions 38 can suppress the formation of a current leakage path in the flat plate portion 22. As a result, ions can be generated stably.

(Ninth Modification)
Next, a ninth modification of the discharge device 100 of the first embodiment will be described with reference to Fig. 11. The discharge device 100 of the ninth modification is mainly different from the first, first, second, third, fourth, fifth, seventh, and eighth modifications of the first embodiment in that it has an outer wall portion 37. Below, the differences between the discharge device 100 of the ninth modification and the first, second, third, fourth, fifth, seventh, and eighth modifications of the first embodiment will be described.

Figure 11 is a diagram showing a discharge device 100 of the ninth modified example. The cover part 2 of the ninth modified example includes a main body part 21 and a pair of openings 20. A pair of electrodes 19 are inserted into the pair of openings 20, respectively. The main body part 21 has a wall part 3, an outer wall part 37, and a flat part 22.

The wall portion 3 includes a pair of seventh wall portions 38. Each of the pair of seventh wall portions 38 surrounds the electrode 19. The pair of seventh wall portions 38 is, for example, cylindrical. The pair of seventh wall portions 38 extend from the flat plate portion 22 in the first direction D1. In other words, the wall portion 3 is not disposed in the space A between the cover portion 2 and the electrode substrate 5.

The outer wall portion 37 extends in the first direction D1. The outer wall portion 37 is formed on the outside of the flat plate portion 22. In other words, the outer wall portion 37 is disposed between the flat plate portion 22 and the storage portion 1. Therefore, the outer wall portion 37 surrounds the flat plate portion 22.

The outer wall portion 37 also surrounds the pair of electrodes 19. The outer wall portion 37 faces the electrodes 19 in a direction intersecting the direction in which the electrode substrate 5 extends. Therefore, when the discharge device 100 is attached to an apparatus, adhesion of water-absorbent substances such as ammonium nitrate to apparatus other than the discharge device 100 is suppressed. As a result, it is possible to suppress the formation of a leak path toward the circuit board of the apparatus to which the discharge device 100 is attached.

In other words, the discharge device 100 of the ninth modified example can prevent the formation of a current leakage path in the flat plate portion 22 by the pair of seventh wall portions 38, and can prevent the formation of a leakage path toward the circuit board of the device to which the discharge device 100 is attached by the outer wall portion 37.

The above describes the embodiments of the present invention with reference to the drawings. However, the present invention is not limited to the above embodiments, and can be implemented in various forms without departing from the gist of the present invention. In addition, various inventions can be formed by appropriately combining multiple components disclosed in each of the above embodiments. For example, some components may be deleted from all components shown in the embodiments. Furthermore, components from the first to sixth variations may be appropriately combined. Furthermore, components from different embodiments may be appropriately combined. The drawings are mainly schematic views of each component for ease of understanding, and the thickness, length, number, spacing, etc. of each component shown in the drawings differ from the actual ones due to the convenience of drawing. In addition, the speed, material, shape, dimensions, etc. of each component shown in the above embodiments are merely examples and are not particularly limited, and various modifications are possible within a range that does not substantially deviate from the configuration of the present invention.

(1) In the discharge device 100 of the first embodiment, the polarity of one of the pair of electrodes 19 is different from the polarity of the other of the pair of electrodes 19, but this is not limited to the above. For example, the pair of electrodes 19 may have the same polarity.

(2) In the discharge device 100 of the first embodiment, the pair of electrodes 19 are needle-shaped or brush-shaped electrodes, but are not limited to this. For example, one of the pair of electrodes 19 may be an induction electrode. The induction electrode surrounds the needle electrode.

(3) In the first embodiment, the discharge device 100 has a pair of electrodes 19, but this is not limited to the present embodiment. For example, the discharge device 100 may have a single electrode 19. Specifically, the discharge device 100 has the electrodes 19, the housing portion 1, the cover portion 2, the electrode substrate 5, the circuit substrate 6, the electronic components 7, the transformer 8, and the encapsulant 9.

The electrode 19 discharges when a voltage is applied. A part of the electrode 19 penetrates the cover part 2. The housing part 1 houses a part of the electrode 19. The housing part 1 houses the electrode board 5, the circuit board 6, the electronic component 7, the transformer 8, and the encapsulating material 9. The electrode board 5 has the electrode 19 arranged thereon. The cover part 2 covers the part of the housing part 1 where the electrode 19 is arranged. The cover part 2 faces the electrode board 5. In addition, there is no circuit board 6 between the electrode board 5 and the cover part 2. Therefore, dust can be prevented from accumulating between the electrodes 19. As a result, it is possible to prevent current leakage from the electrode 19 due to dust accumulated between the electrodes 19.

(4) In the discharge device 100 of the first embodiment, the encapsulant 9 is disposed on the surface of the electrode substrate 5 on the second direction D2 side, but the encapsulant 9 may also be disposed on the surface of the electrode substrate 5 on the first direction D1 side. In this case, the cover portion 2 can prevent dust from accumulating on the encapsulant 9 on the first direction D1 side of the electrode substrate 5.

(5) Although the main body 21 of the discharge device 100 in the first embodiment has one first wall 31, this is not limited thereto. For example, the main body 21 of the discharge device 100 may have multiple first walls 31. By arranging multiple first walls 31 on the flat plate portion 22, the distance along the surface of the main body 21 from opening 20 to opening 20 becomes even longer. Therefore, when a substance that reduces the insulating performance adheres to the main body 21, the formation of a current leakage path between electrodes 19 can be further delayed. As a result, the period during which ions can be generated stably can be further extended.

(6) The main body 21 of the discharge device 100 of the second modified example of the first embodiment has one third wall 33 and one fourth wall 34, but is not limited to this. For example, the main body 21 may have multiple recesses. Specifically, the main body 21 of the discharge device 100 may have multiple third wall 33 and multiple fourth wall 34. The flat plate 22 may have multiple third flat plate 223. Therefore, by arranging multiple walls 3 on the flat plate 22, the distance along the surface of the main body 21 from opening 20 to opening 20 becomes even longer. Therefore, when a substance that reduces the insulating performance adheres to the main body 21, the formation of a current leakage path between the electrodes 19 can be further delayed. As a result, the period during which ions can be generated more stably can be extended.

(7) The flat plate portion 22 of the discharge device 100 of the seventh modified example has a corrugated shape, but is not limited to this. For example, the first flat plate portion 221 of the fifth modified example of the first embodiment may have a corrugated shape. Also, the second flat plate portion 222 of the fifth modified example of the first embodiment may have a corrugated shape. Also, the third flat plate portion 223 of the fifth modified example of the first embodiment may have a corrugated shape.

The present invention provides a discharge device and has industrial applicability.

2: Cover portion 3: Wall portion 5: Electrode board 6: Circuit board 13: Opening 19: Electrode 20: Opening 21: Main body portion 22: Flat plate portion 31: First wall portion 32: Second wall portion 33: Third wall portion 34: Fourth wall portion 35: Fifth wall portion 36: Sixth wall portion 37: Outer wall portion 100: Discharge device 221: First flat plate portion 222: Second flat plate portion 223: Third flat plate portion D1: First direction D2: Second direction LA: Inner diameter LB: Inner diameter

Claims (13)

A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate,
A portion of each of the pair of electrodes penetrates the cover portion,
There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes each penetrate the cover portion through the pair of openings,
The main body portion is
a wall portion extending in a direction intersecting the electrode substrate;
a flat plate portion extending along the electrode substrate;
having
the wall portion is disposed between the pair of openings and has a cylindrical shape surrounding the electrode,
The wall portion extends in a first direction from the electrode substrate toward the flat portion and in a second direction from the flat portion toward the electrode substrate . The discharge device according to claim 1 , wherein an inner diameter of the cylindrical shape of the wall portion increases toward an end of the electrode on the first direction side. The flat plate portion has a corrugated shape,
The wave shape is disposed in a portion of the flat plate portion between the pair of openings.
The discharge device according to claim 1 or 2 . A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate;
Equipped with
A portion of each of the pair of electrodes penetrates the cover portion,
There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes each penetrate the cover portion through the pair of openings,
The main body portion is
a wall portion extending in a direction intersecting the electrode substrate;
a flat plate portion extending along the electrode substrate;
having
the wall portion is disposed between the pair of openings and on the flat plate portion, and extends in a first direction from the electrode substrate toward the flat plate portion;
The flat plate portion has a corrugated shape,
A discharge device , wherein the wave shape is disposed in a portion of the flat plate portion between the pair of openings . A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate;
Equipped with
A portion of each of the pair of electrodes penetrates the cover portion,
There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes each penetrate the cover portion through the pair of openings,
The main body portion is
a wall portion extending in a direction intersecting the electrode substrate;
a flat plate portion extending along the electrode substrate;
having
the wall portion is disposed between the pair of openings and on the flat plate portion, and extends in a first direction from the electrode substrate toward the flat plate portion;
the wall portion includes a pair of wall portions extending from the flat plate portion toward a second direction toward the electrode substrate,
The flat plate portion is
a first flat plate portion extending from one of the pair of openings to an end portion of one of the pair of wall portions on the first direction side;
a second flat plate portion extending from the other of the pair of openings to an end portion of the other of the pair of wall portions on the first direction side;
a third flat plate portion extending from an end portion in the second direction of the one wall portion to an end portion in the second direction of the other wall portion;
A discharge device comprising : The main body further includes an outer wall surrounding the pair of electrodes,
The discharge device according to claim 1 , wherein the outer wall portion faces the pair of electrodes in an extending direction of the electrode substrate. A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate;
Equipped with
A portion of each of the pair of electrodes penetrates the cover portion,
There is no circuit board on which a circuit is formed between the electrode substrate and the cover portion,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes each penetrate the cover portion through the pair of openings,
the main body portion has a wall portion extending in a direction intersecting the electrode substrate and an outer wall portion surrounding the pair of electrodes,
The wall portion is disposed between the pair of openings,
The outer wall portion faces the pair of electrodes in an extending direction of the electrode substrate . The main body portion has a flat plate portion extending along the electrode substrate,
The discharge device according to claim 7 , wherein the wall portion is disposed on the flat plate portion and extends in a first direction from the electrode substrate toward the flat plate portion. The main body portion has a flat plate portion extending along the electrode substrate,
The discharge device according to claim 7 or 8 , wherein the wall portion is disposed on the flat plate portion and extends in a second direction from the flat plate portion toward the electrode substrate. The discharge device according to claim 9 , wherein the wall portion extends from the flat plate portion until it abuts against the electrode substrate. A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes are inserted into the pair of openings,
The main body portion has an outer wall portion surrounding the pair of electrodes,
the outer wall portion faces the pair of electrodes in an extending direction of the electrode substrate,
A discharge device, wherein there is no circuit board on which a circuit is formed between the electrode substrate and the cover portion. A pair of electrodes that discharge when a voltage is applied;
an electrode substrate on which the pair of electrodes is disposed;
a cover portion facing the electrode substrate;
Equipped with
A portion of each of the pair of electrodes penetrates the cover portion,
The cover portion includes a main body portion and a pair of openings disposed in the main body portion,
The pair of electrodes each penetrate the cover portion through the pair of openings,
The main body portion is
a wall portion extending in a direction intersecting the electrode substrate;
a flat plate portion extending along the electrode substrate;
having
The wall portion is cylindrical and surrounds the electrode, and extends in one of a first direction from the electrode substrate toward the flat portion and a second direction from the flat portion toward the electrode substrate . The discharge device according to claim 12 , wherein the wall portion extends in the other of the first direction and the second direction.

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