JP2009164036A - Ion generating element - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ion generating element achieving effective ion generation and ready manufacture. <P>SOLUTION: The ion generating element 1 has a substrate 10 and an ion generation electrode 20 formed on the substrate 10 using a membrane conductor to generate ions by high-voltage application. The ion generation electrode 20 includes a discharge part 21 having a peak 22. The peak 22 of the discharge part 21 is situated above the substrate 10 at a position of a distance of less than 0.6 mm away from an end face 12 of the substrate 10. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an ion generating element.

  Conventionally, as a method for generating ions, there are a method using a Leonard effect for generating ions by giving an impact to water and a method for generating ions electrically by applying a high voltage to an electrode. The ions generated in this way are used for static elimination, inactivation treatment of bacteria and viruses, or for increasing comfort by ions. In addition, air can be purified by discharge energy when ions are generated, or an air flow can be generated by moving ions in the air.

  In a method in which a high voltage is applied to the electrode to discharge and ions are generated by dissociating molecules in the air, the ion is generated by applying a high voltage between the needle-like electrode or the fine wire electrode and the counter electrode. Can be generated. An ion generating element using this method is generally used because the element structure is relatively simple.

  In the method of generating ions by applying a high voltage to the electrodes, in general, the voltage required to generate a certain amount of ions is as much as possible from the viewpoint of safety, miniaturization of the high voltage generation circuit, and power saving. A low voltage is desirable. Therefore, a needle electrode or a plate-like electrode having a portion formed at an acute angle is used as an ion generating electrode of an ion generating element that generates ions by applying a high voltage to the electrode.

  For example, Japanese Patent Laying-Open No. 2005-63827 (Patent Document 1) describes an ion generator in which an extra fine wire of 100 μm or less is used as a discharge electrode.

  Japanese Utility Model Laid-Open No. 6-31099 (Patent Document 2) and Japanese Patent Laid-Open No. 6-109274 (Patent Document 3) disclose a plate-like ion generating electrode having a sawtooth having a tip formed at 45 ° or less. Is described.

  Japanese Patent Laying-Open No. 2004-4334 (Patent Document 4) describes a corona discharge device having a metal electrode having a plurality of needle-like protrusions.

  On the other hand, in the ion wind generator described in Japanese Patent Laid-Open No. 2001-80908 (Patent Document 5), in order to strictly manage the installation interval between the needle electrode and the outer electrode by exchanging the needle electrode or removing it by cleaning. The needle electrode and the outer electrode are integrated.

Japanese Laid-Open Patent Publication No. 64-2075 (Patent Document 6) describes a creeping discharge type solid discharge device in which a voltage is applied between electrodes formed with a dielectric layer interposed therebetween. In this solid-state discharge device, since a dielectric is interposed between the electrodes, ions can generally be generated at a lower voltage than a method of applying a voltage between the electrodes in the air.
JP 2005-63827 A Japanese Utility Model Publication No. 6-31099 JP-A-6-109274 JP 2004-4334 A Japanese Patent Laid-Open No. 2001-80908 JP-A 64-2075

  However, the method of generating ions by the Leonard effect has a problem that only negative ions are generated and positive ions cannot be generated. Moreover, since water is used, there is a problem that air is humidified and the apparatus becomes large.

  As in the case of the ion generator described in Japanese Patent Application Laid-Open No. 2005-63827 (Patent Document 1), a case where an extra fine wire electrode is used as a needle-like discharge electrode, or in Japanese Patent Application Laid-Open No. 2004-4334 (Patent Document 4). When using the metal electrode having the needle-like projection described, when using the needle-like electrode described in JP-A-2001-80908 (Patent Document 5), the tip diameter of the needle-like electrode is reduced. Therefore, it is necessary to process the tip of the electrode with high accuracy, which causes a problem that the processing becomes difficult and the processing cost becomes expensive.

  Similarly, when using a plate-like ion generating electrode having saw blades described in Japanese Utility Model Laid-Open No. 6-31099 (Patent Document 2) and Japanese Patent Laid-Open No. 6-109274 (Patent Document 3), In order to reduce the tip diameter, it is necessary to process the tip of the electrode with high accuracy, and there is a problem that the processing becomes difficult and the processing cost becomes expensive.

  On the other hand, in the solid-state discharge device described in Japanese Patent Application Laid-Open No. 64-2075 (Patent Document 6), ions generated on the electrode formed by the printing method remain in the vicinity of the electrode. Requires ventilation over the electrodes. Therefore, when a fan that generates air is included, there is a problem that power consumption necessary for generating ions increases.

  Therefore, an object of the present invention is to provide an ion generating element that can efficiently generate ions and can be easily manufactured.

  An ion generating element according to the present invention includes a substrate and an ion generating electrode that is formed on the substrate by a film-like conductor and generates ions by applying a high voltage. The tip of the discharge part is disposed on the substrate at a position where the distance from the end surface of the substrate is 0.6 mm or less.

  The ion generating electrode composed of a film-like conductor is formed into a sharp pattern with a thin film having a film thickness of 20 μm or less by using a technique such as screen printing or etching. With such a thin film conductor, an ion generating electrode having a small tip diameter can be easily formed, so that the ion generating electrode can be manufactured at low cost.

  In addition, since it is easy to form a plurality of ion generating electrodes side by side on a substrate, an ion generating element can be manufactured efficiently and at low cost.

  Further, the tip of the discharge part of the ion generating electrode is arranged on the substrate at a position where the distance from the end surface of the substrate is 0.6 mm or less, thereby effectively generating ions, for example, including a blower fan. Even if it does not exist, the effect by ion can be acquired.

  By doing so, it is possible to provide an ion generating element that can efficiently generate ions and can be easily manufactured.

  The ion generating element according to the present invention preferably includes an induction electrode formed on a substrate by a film-like conductor.

  By doing so, the accuracy of the positional relationship between the ion generating electrode and the induction electrode can be increased. For example, in a system in which ions are sent out by an electric field, the relative position between the ion generating electrode and the induction electrode greatly affects the amount of ions delivered from the ion generating element. Therefore, by increasing the accuracy of the positional relationship between the ion generation electrode and the induction electrode in this way, it is possible to reduce variations in the ion delivery amount characteristics of the ion generation element.

  In the ion generating element according to the present invention, the ion generating electrode preferably includes a metal oxide.

  The conventional ion generating element has a problem that the ion generating electrode is consumed due to the generation of ions and the sputtering phenomenon caused by the collision of the ions with the electrode. Since the metal oxide has high heat resistance and high durability against ion impact, the ion generating electrode includes the metal oxide, so that the ion generating electrode can be formed with a long life and less consumed by the generation of ions.

  In the ion generating element according to the present invention, the metal oxide preferably contains ruthenium oxide.

  Since ruthenium oxide has high durability against ion impact and is less consumed by the generation of ions, the ion generating electrode can contain a ruthenium oxide, whereby a long-life ion generating element can be formed. In general, metal oxides have low electrical conductivity and high electrical resistance, so there is a drawback that heat loss occurs when current flows and power loss occurs. However, since the electrical resistance of ruthenium oxide is relatively low, It is particularly suitable as a material for the generating electrode. By doing in this way, an ion generating electrode with little power loss can be formed.

  As described above, according to the present invention, it is possible to provide an ion generating element that can efficiently generate ions and can be easily manufactured.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a front view (A) showing the whole of an ion generating element and a power source as a first embodiment of the present invention, and a side view (B) when the ion generating element shown in FIG. It is.

  As shown in FIG. 1, the ion generating element 1 includes a substantially square substrate 10 and an ion generating electrode 20 formed on the substrate 10 by a printing method. The ion generation electrode 20 includes a discharge part 21 having a tip 22 and a lead wire connection terminal 24.

The substrate 10 is a 96% alumina substrate. The discharge part 21 of the ion generating electrode 20 is printed on the substrate 10 with a thick film using a ruthenium oxide (RuO ₂ ) material (manufactured by DuPont, product number: QS871) as a metal oxide of a conductor, and is printed at 850 ° C. for 10 minutes. It is formed by a thick film printing / firing method for firing. The tip angle of the tip 22 of the discharge part 21 is formed at an acute angle of 23.5 °. The film thickness of the discharge part 21 is 7-11 micrometers. The lead wire connection terminal 24 is formed by printing and baking on the substrate 10 using a silver palladium (AgPd) conductor (manufactured by DuPont, product number: # 5164N). The discharge part 21 is fired after being printed so as to form an overlap part 23 that overlaps a part of the lead wire connection terminal 24 that has been printed and fired in advance. The distance A from the tip 22 of the discharge part 21 to the end surface 12 of the substrate 10 is 0.6 mm or less.

  A high voltage is applied to the discharge portion 21 of the ion generating element 1 by the high voltage power supply device 40. When a high voltage is applied, a discharge is generated in the discharge unit 21, and molecules in the air around the discharge unit 21 are dissociated to generate ions. The ions generated in this way are used for static elimination, inactivation of bacteria and viruses, or for increasing comfort by ions. Further, it is possible to purify the air by the discharge energy at the time of ion generation, or to generate an air flow by moving ions in the air in an electric field.

  As described above, the ion generating element 1 includes the substrate 10 and the ion generating electrode 20 that is formed on the substrate 10 by the film-like conductor and generates ions by applying a high voltage. The electrode 20 includes a discharge portion 21 having a tip 22, and the tip 22 of the discharge portion 21 is disposed on the substrate 10 at a position where the distance from the end surface 12 of the substrate 10 is 0.6 mm or less.

  The ion generating electrode 20 composed of a film-like conductor is formed into a sharp pattern with a thin film having a thickness of 20 μm or less by using a technique such as screen printing or etching. Since such a thin film conductor can easily form the ion generating electrode 20 having a small tip diameter, the ion generating electrode 20 can be manufactured at low cost.

  Moreover, since it is easy to form a plurality of ion generating electrodes 20 side by side on the substrate 10, the ion generating element 1 can be manufactured efficiently and at low cost.

  Further, the tip 22 of the discharge portion 21 of the ion generating electrode 20 is arranged on the substrate 10 at a position where the distance from the end surface 12 of the substrate 10 is 0.6 mm or less, thereby effectively generating ions, For example, the effect of ions can be obtained without a blower fan.

  By doing in this way, the ion generating element 1 which can generate ion efficiently and can be produced easily can be provided.

  Moreover, in the ion generating element 1, the ion generating electrode 20 contains a metal oxide.

  The conventional ion generating element has a problem that the ion generating electrode is consumed due to the generation of ions and the sputtering phenomenon caused by the collision of the ions with the electrode. Since the metal oxide has high heat resistance and high durability against ion impact, the ion generating electrode includes the metal oxide, so that the ion generating electrode can be formed with a long life and less consumed by the generation of ions.

  In the ion generating element 1, the metal oxide contains ruthenium oxide.

  Since ruthenium oxide has high durability against ion impact and is less consumed due to the generation of ions, the ion generating electrode 20 contains ruthenium oxide, whereby the long-life ion generating element 1 can be formed. In general, metal oxides have low electrical conductivity and high electrical resistance, so there is a drawback that heat loss occurs when current flows and power loss occurs. However, since the electrical resistance of ruthenium oxide is relatively low, It is particularly suitable as a material for the generation electrode 20. By doing in this way, the ion generating electrode 20 with little power loss can be formed.

(Second Embodiment)
FIG. 2 is a front view (A) showing the whole of an ion generating element and a power source as a second embodiment of the present invention, and a side view (B) when the ion generating element shown in FIG. It is.

  As shown in FIG. 2, the ion generating element 2 includes a U-shaped substrate 11, an ion generating electrode 20 formed on the substrate 11 by a printing method, and two electrodes formed on the substrate 11 by a printing method. And an induction electrode 30. The ion generation electrode 20 includes a discharge part 21 having a tip 22 and a lead wire connection terminal 24. In the ion generating element 2, the side of the substrate 11 where the U-shape is open is the front. The two induction electrodes 30 are arranged in parallel with a certain distance on the left front side and the right front side of the tip 22 on the front side of the tip 22 of the discharge part 21. A lead wire connection terminal 31 is connected to the induction electrode 30.

The substrate 11 is a 96% alumina substrate. The discharge part 21 of the ion generating electrode 20 has a thickness obtained by printing a thick film on the substrate 11 using a ruthenium oxide (RuO ₂ ) material (manufactured by DuPont, product number: QS871) as a metal oxide and baking at 850 ° C. for 10 minutes. It is formed by film printing / firing method. The tip angle of the tip 22 of the discharge part 21 is formed at an acute angle of 23.5 °. The film thickness of the discharge part 21 is 7-11 micrometers. The lead wire connection terminal 24 and the induction electrode 30 are formed on the substrate 11 by printing and baking using a silver palladium (AgPd) conductor (manufactured by DuPont, product number: # 5164N). The discharge part 21 is fired after being printed so as to form an overlap part 23 that overlaps a part of the lead wire connection terminal 24 that has been printed and fired in advance. The distance A from the tip 22 of the discharge part 21 to the end surface 12 of the substrate 11 is 0.6 mm or less.

  A high voltage is applied to the discharge portion 21 of the ion generating element 2 by the high voltage power supply device 40. When a high voltage is applied, a discharge is generated in the discharge unit 21, and molecules in the air around the discharge unit 21 are dissociated to generate ions. The induction electrode 30 is grounded through a lead wire connection. By grounding the induction electrode 30, it becomes difficult to be affected by charging from objects around the ion generating element 2. Further, the ion generating electrode 20 and the induction electrode 30 are formed on the same substrate 11. Therefore, since the relative position between the ion generating electrode 20 and the induction electrode 30 is not shifted, variation in the characteristics of the ion generating element 2 due to the shift of the fixed position between the ion generating electrode 20 and the induction electrode 30 can be suppressed.

  As described above, the ion generating element 2 includes the substrate 11 and the ion generating electrode 20 that is formed on the substrate 11 by the film-like conductor and generates ions by applying a high voltage. The electrode 20 includes a discharge portion 21 having a tip 22, and the tip 22 of the discharge portion 21 is disposed on the substrate 11 at a position where the distance from the end surface 12 of the substrate 11 is 0.6 mm or less.

  The ion generating electrode 20 composed of a film-like conductor is formed into a sharp pattern with a thin film having a thickness of 20 μm or less by using a technique such as screen printing or etching. Since such a thin film conductor can easily form the ion generating electrode 20 having a small tip diameter, the ion generating electrode 20 can be manufactured at low cost.

  Moreover, since it is easy to form a plurality of ion generating electrodes 20 side by side on the substrate 11, the ion generating element 2 can be manufactured efficiently and at low cost.

  Further, the tip 22 of the discharge portion 21 of the ion generating electrode 20 is arranged on the substrate 11 at a position where the distance from the end face 12 of the substrate 11 is 0.6 mm or less, thereby effectively generating ions, For example, the effect of ions can be obtained without a blower fan.

  By doing in this way, the ion generating element 2 which can generate | occur | produce ion efficiently and can be produced easily can be provided.

  The ion generating element 2 includes an induction electrode 30 formed on the substrate 11 by a film-like conductor.

  By doing in this way, the precision of the positional relationship of the ion generating electrode 20 and the induction | dielectric electrode 30 can be made high. For example, in the method of sending out ions by an electric field, the relative position between the ion generating electrode 20 and the induction electrode 30 greatly affects the amount of ions delivered from the ion generating element 2. Thus, by increasing the accuracy of the positional relationship between the ion generating electrode 20 and the induction electrode 30 in this way, it is possible to reduce variations in the ion delivery amount characteristics of the ion generating element 2.

  Moreover, in the ion generating element 2, the ion generating electrode 20 contains a metal oxide.

  The conventional ion generating element has a problem that the ion generating electrode is consumed due to the generation of ions and the sputtering phenomenon caused by the collision of the ions with the electrode. Since the metal oxide has high heat resistance and high durability against ion impact, the ion generating electrode includes the metal oxide, so that the ion generating electrode can be formed with a long life and less consumed by the generation of ions.

  In the ion generating element 2, the metal oxide contains ruthenium oxide.

  Since ruthenium oxide has high durability against ion impact and is less consumed by the generation of ions, the ion generating electrode 20 contains ruthenium oxide, whereby the long-life ion generating element 2 can be formed. In general, metal oxides have low electrical conductivity and high electrical resistance, so there is a drawback that heat loss occurs when current flows and power loss occurs. However, since the electrical resistance of ruthenium oxide is relatively low, It is particularly suitable as a material for the generation electrode 20. By doing in this way, the ion generating electrode 20 with little power loss can be formed.

  As one effect of the ion generating element of the present invention, in order to investigate the ion generation amount, the ion amount at a distance of 30 cm from the ion generating element was measured.

  For the ion generating element of the first embodiment, Embodiment 1A in which the distance from the tip of the discharge part to the end face of the substrate was 0.0 mm, and the distance from the tip of the discharge part to the end face of the substrate was 0.6 mm The amount of ions was measured using Form 1B and the ion generating element of Comparative Form 1 in which the distance from the tip of the discharge part to the end face of the substrate was 0.8 mm.

  The output terminal of the high-voltage power supply was connected to the lead wire connection terminal of Embodiment 1A, Embodiment 1B, and Comparative Embodiment 1, and a voltage of DC-2.8 kV was applied. An ion counter (manufactured by Asahi System, model number: MY1210II) was installed at a position 30 cm away from the tip of the discharge part of the ion generating electrode, and the amount of ions was measured. The measurement results are shown in Table 1.

As shown in Table 1, in Embodiment 1A and Embodiment 1B, ion amounts of 320,000 / cm ³ and 250,000 / cm ³ are measured, respectively. On the other hand, in Comparative Example 1, the measured amount of ions was 0,000 ions / cm ³ . From this, it can be seen that the tip of the discharge part of the ion generating electrode can generate ions effectively by being disposed on the substrate at a distance of 0.6 mm or less from the end surface of the substrate. It was. Since an ion amount of 25 to 320,000 / cm ³ is obtained at a position 30 cm away from the ion generating element, the effect of ions, that is, neutralization or bacteria / virus inactivation treatment is performed. Or, it is possible to expect an effect of increasing comfort by ions or generating an air flow by moving ions in the air.

  Next, the ion generation amount of the ion generating element provided with the induction electrode was examined. In the ion generating element of the second embodiment, using the ion generating element of the embodiment 2A in which the tip of the discharge part is disposed at a distance of 0.0 mm from the end face of the substrate, the tip of the ion generating electrode is the same as in Example 1. The amount of ion generation was measured at a distance of 30 cm from the surface. The measurement results are shown in Table 2.

As shown in Table 2, by providing the induction electrode, the ion generating element of Embodiment 2A is compared with the ion generating element of Embodiment 1A in which the tip is disposed at a position of 0.0 mm from the end surface of the substrate. became measured ion amount 30,000 / cm ³ increase to 350,000 / cm ^3.

  By grounding the induction electrode as in the ion generating element of the second embodiment, it becomes difficult to be affected by charging from an object around the ion generating element. In addition, since the ion generating electrode and the induction electrode are formed on the same substrate, the relative position between the ion generating electrode and the induction electrode does not shift. Variations in the characteristics of the generating elements can be suppressed.

  As an effect of each ion generating element of the present invention, in order to investigate the durability of the ion generating electrode, the ion generation amount at the initial stage and after 3000 hours was measured. The measurement method was the same as in Example 1.

  A discharge part was formed using silver palladium (AgPD) (manufactured by DuPont, product number: # 5164), which is a general thick film conductor material, and the distance from the tip of the discharge part to the end face of the substrate was set to 0.0 mm. A discharge part is formed using the ion generating element of Embodiment 3A and gold (Au) which is a general thick film conductor material (manufactured by Tanaka Kikinzoku Kogyo, product number: TR-1534), and the substrate is formed from the tip of the discharge part. For the ion generating element of Embodiment 3B in which the distance to the end face of the electrode is 0.0 mm and the ion generating element of Embodiment 1A used in Example 1, the initial ion generation amount and the ion generation amount after 3000 hours are as follows: It was measured. The ion generating elements of Embodiment 1A, Embodiment 3A, and Embodiment 3B are different in the material of the discharge part, but the other configurations are the same. Table 3 shows the measurement results.

As shown in Table 3, the initial ion generation amount was 320,000 / cm ³ in any of Embodiment 1A, Embodiment 3A, and Embodiment 3B. However, after lapse of 3000 hours, although ions generated in the element 180,000 / cm ³ ions embodiment 1A of the discharge portion is formed by oxidation of ruthenium occurs, embodiments 3A the discharge portion is formed of silver palladium ions In the generating element and the ion generating element of Embodiment 3B in which the discharge part was formed of gold, the measured ion amount was 0,000 ions / cm ³ .

  Thus, it turned out that the ion generating element excellent in durability can be obtained because a discharge part contains ruthenium oxide.

  It should be considered that the embodiments and examples disclosed above are illustrative and non-restrictive in every respect. The scope of the present invention is shown not by the above embodiments and examples but by the scope of the claims, and includes all modifications and variations within the meaning and scope equivalent to the scope of the claims.

As a first embodiment of the present invention, there are a front view (A) showing the whole of an ion generating element and a power source, and a side view (B) when the ion generating element shown in (A) is viewed from the right direction. As 2nd Embodiment of this invention, it is a front view (A) which shows the whole of an ion generating element and a power supply, and a side view (B) when the ion generating element shown to (A) is seen from the right direction.

Explanation of symbols

  1, 2: ion generating element, 10, 11: substrate, 12: end face, 20: ion generating electrode, 21: discharge part, 22: pointed tip, 30: induction electrode.

Claims (4)

A substrate,
An ion generating electrode formed on the substrate by a film-like conductor and generating ions by applying a high voltage;
The ion generating electrode includes a discharge part having a tip,
The tip of the discharge part is an ion generating element arranged on the substrate at a position where the distance from the end surface of the substrate is 0.6 mm or less.   The ion generating element according to claim 1, comprising an induction electrode formed on the substrate by a film-like conductor.   The ion generating element according to claim 1, wherein the ion generating electrode includes a metal oxide.   The ion generating element according to claim 3, wherein the metal oxide includes ruthenium oxide.

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