JP2010244839A - Ion generator and discharge device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ion generator for maintaining stable ion generating performance over a long period of time without needing to clean and replace needle electrodes. <P>SOLUTION: The ion generator generates ions by applying and discharging voltage between needle discharge electrodes 11, 12, 13 and a dielectric electrode 2. The ion generator includes a plurality of the needle discharge electrodes 11, 12, 13 and includes insulating discharge restraining members 51, 52 covering the tip portions of the plurality of the needle discharge electrodes 11, 12, 13 individually, and a discharge electrode selecting means 6 selecting the needle discharge electrodes 11, 12, 13 to discharge by detaching the discharge restraining members 51, 52 from the tip portions of the needle discharge electrodes 12, 13. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention is used in an ion generator, an ion generator, a radical generator, and the like that generate ions by applying a voltage between a needle-like discharge electrode and a dielectric electrode to cause discharge, and the needle-like discharge electrode and the dielectric electrode. The present invention relates to a discharge device that discharges by applying a voltage therebetween.

In recent years, electric devices such as air purifiers and dehumidifiers that generate ions by a built-in ion generator and perform functions such as sterilization, deodorization, or refreshing of air are becoming widespread.
As a method for generating ions, a corona discharge that is electrically generated by applying a high voltage to a needle electrode and discharging it at atmospheric pressure, a method in which a high voltage is applied to a metallic wire to discharge, and a dielectric between the electrodes. There are known creeping discharge systems that generate plasma in the air with a structure that sandwiches the body.

Specifically, for example, Patent Document 1 includes at least one needle electrode supported by a holding body and a ground electrode similarly supported by the holding body, and a high voltage is provided between the needle electrode and the ground electrode. Is applied to generate a corona discharge at the tip of the needle electrode and generate ions by this corona discharge.
Patent Document 2 includes a rectifying duct having a cylindrical portion provided with a counter electrode and a boss portion, and a discharge module that is detachably attached to the cylindrical portion. Air is supplied to the rectifying duct by a fan of a blower. A supplied static eliminator is disclosed. The discharge module has a holder fitted to the boss portion and a plurality of discharge electrodes attached to the holder and projecting radially outward toward the counter electrode. When foreign matter or the like adheres to the tip of the discharge electrode, or when the discharge electrode deteriorates, the discharge module is removed from the boss portion.

  Patent Document 3 discloses an ion generating element including a dielectric, a discharge electrode disposed on the dielectric, and a dielectric electrode disposed inside the dielectric and receiving the action of the discharge electrode. ing. A socket-type power supply unit for energizing the ion generating element has a detachable plug part, and the plug part is provided with electrode contacts of a discharge electrode and a dielectric electrode.

JP 2004-18348 A JP 2006-196380 A JP 2006-228646 A

In the ion generator and discharge device using corona discharge as described above, charged dust or the like may adhere to the tip of the discharge needle (needle electrode) of the discharge electrode depending on the usage environment. When dust adheres to and accumulates on the tip of the discharge needle, corona discharge is less likely to occur and ion generation performance is reduced. For this reason, it is desirable to periodically clean the tip of the discharge needle.
In order to solve such a problem, a method for improving workability at the time of replacement or cleaning has been proposed by adopting a configuration in which the ion generating element is detachable as, for example, a plug + socket.

  However, in the conventional ion generator and discharge device, the cleaning of the needle electrode is left to the user's own work, and there is a problem that the needle electrode is damaged during cleaning. In addition, it has been devised to replace the needle electrode with deterioration, but there is a problem that the replacement cannot be performed quickly unless a part for that purpose is prepared separately.

The present invention has been made in view of the circumstances as described above, and provides an ion generator that can maintain stable ion generation performance over a long period of time without the need to clean and replace needle-like electrodes. With the goal.
Another object of the present invention is to provide a discharge device that does not require cleaning and replacement of the needle electrode and can maintain stable discharge performance over a long period of time.

  An ion generator according to the present invention includes a plurality of needle-like discharge electrodes in an ion generator that generates ions by applying a voltage between a needle-like discharge electrode and a dielectric electrode to cause discharge. Insulating discharge suppression member for individually covering the tip portion of the needle-like discharge electrode, and discharge electrode selection means for selecting the needle-like discharge electrode to be discharged by removing the discharge suppression member from the tip portion of the needle-like discharge electrode It is characterized by providing.

  In this ion generator, ions are generated by applying a voltage between the acicular discharge electrode and the dielectric electrode to cause discharge. A plurality of needle-like discharge electrodes are provided, and an insulating discharge suppressing member individually covers the tip portions of the plurality of needle-like discharge electrodes. The discharge electrode selection means selects the acicular discharge electrode to be discharged by removing the discharge suppressing member from the tip portion of the acicular discharge electrode.

  The ion generator according to the present invention is characterized in that the discharge suppressing member is a cap that covers a tip portion of the acicular discharge electrode.

  The ion generator according to the present invention is characterized in that each tip portion of the plurality of needle-like discharge electrodes has the same distance from the dielectric electrode.

  The ion generator according to the present invention further includes a timer for accumulating the operation time, and each time the timer counts a predetermined time, the discharge electrode selection means attaches one of the discharge suppression members to the tip of the acicular discharge electrode. It is configured to be removed from the part.

  In this ion generator, the timer accumulates its operating time, and each time the timer measures a predetermined time, the discharge electrode selection means removes one of the discharge suppression members from the tip of the needle-like discharge electrode.

  The ion generator according to the present invention further comprises a detector for detecting the amount of generated ions, and means for determining whether or not the amount of ions detected by the detector is smaller than a predetermined amount. The discharge electrode selection means is configured to remove one of the discharge suppression members from the tip portion of the needle-like discharge electrode when it is determined that the discharge electrode is smaller.

  In this ion generator, the detector detects and determines the amount of ions generated, and determines whether or not the amount of ions detected by the detector is smaller than a predetermined amount. When the determination means determines that the discharge amount is smaller than the predetermined amount, the discharge electrode selection means removes one of the discharge suppression members from the tip portion of the acicular discharge electrode.

  In the ion generator according to the present invention, when the discharge electrode selecting means removes one of the discharge suppression members from the tip portion of the needle-like discharge electrode, the discharge electrode selecting means discharges to the tip portion of the other needle-like discharge electrode that has been selected. It is configured to cover the restraining member.

  A discharge device according to the present invention is a discharge device that discharges by applying a voltage between a needle-shaped discharge electrode and a dielectric electrode inside a housing, and includes a plurality of the needle-shaped discharge electrodes. And a movable plate having an opening through which the tip of the needle-like discharge electrode can be viewed from the housing, and by moving the movable plate, the tip of the needle-like discharge electrode Is covered with the covering portion or viewed from the opening, and a needle-like discharge electrode to be discharged is selected.

  In this discharge device, discharge is performed by applying a voltage between the acicular discharge electrode and the dielectric electrode inside the housing. A plurality of needle-like discharge electrodes are provided, and the movable plate has a covering portion that covers the tip portion of the needle-like discharge electrode and an opening portion that allows the tip portion of the needle-like discharge electrode to be viewed from the housing. By moving the movable plate, the tip portion of the needle-like discharge electrode is covered with the covering portion or viewed through the opening, and the needle-like discharge electrode to be discharged is selected.

  The discharge device according to the present invention is characterized in that the covering portion is made of an insulator.

  In the discharge device according to the present invention, the voltage is an alternating current or a direct current whose average value is not 0, and the needle-like discharge electrode whose tip portion is coated on the covering portion has a surface on the tip portion side of the covering portion. It is configured such that discharge is suppressed by charging with the voltage.

  In this discharge device, the voltage applied between the acicular discharge electrode and the dielectric electrode is an alternating current or direct current whose average value is not 0, and the acicular discharge electrode having a covering portion covered with the tip portion is the tip portion of the covering portion. When the side surface is charged by this voltage, the discharge is suppressed.

  The discharge device according to the present invention is characterized in that the movable plate is fitted into the housing so as to be slidable in the plate surface direction.

  The discharge device according to the present invention is characterized in that the movable plate is pivotally attached to the casing so as to be rotatable in the plate surface direction.

  The discharge device according to the present invention is characterized in that the covering portion is configured to come into contact with a tip portion of a needle-like discharge electrode by sliding or rotating the movable plate in the plate surface direction. To do.

  According to the ion generator according to the present invention, it is not necessary to clean and replace the needle-like electrode, and an ion generator that can maintain stable ion generation performance over a long period of time can be realized.

  According to the discharge device according to the present invention, it is not necessary to clean and replace the needle electrode, and it is possible to realize a discharge device that can maintain stable discharge performance over a long period of time.

It is a mimetic diagram showing roughly composition of an embodiment of an ion generator concerning the present invention. It is a mimetic diagram showing roughly composition of an embodiment of an ion generator concerning the present invention. It is a mimetic diagram showing roughly composition of an embodiment of an ion generator concerning the present invention. It is a mimetic diagram showing roughly composition of an embodiment of an ion generator concerning the present invention. It is sectional drawing which shows typically the principal part structure of embodiment of the discharge device which concerns on this invention. FIG. 6 is a perspective view showing the discharge device shown in FIG. 5 in a perspective view. It is a perspective view which shows the structural example of a movable plate. It is a perspective view which shows perspectively the principal part structure of embodiment of the discharge device concerning this invention.

Hereinafter, the present invention will be described with reference to the drawings illustrating embodiments thereof.
(Embodiment 1)
FIG. 1 is a schematic diagram showing a main configuration of Embodiment 1 of an ion generator according to the present invention.
In this ion generator, a plurality of needle-like electrodes (needle-like discharge electrodes) 11, 12, and 13 are supported as a discharge electrode by a casing (not shown) of the ion generator, and are arranged side by side. In the first embodiment, the case where the needle-like electrode is composed of three will be described. The tip portions of the needle-like electrodes 12 and 13 are covered with caps (discharge suppressing members) 51 and 52, respectively. The needle electrode 11 is not covered with a cap.

The caps 51 and 52 are made of, for example, high-voltage insulating rubber, and the tips 12 and 13 are not discharged by covering the tip portions thereof. Instead of the caps 51 and 52, the tip portions of the needle-like electrodes 12 and 13 may be covered with two, for example, cylindrical discharge suppressing members.
The induction electrode 2 for generating a corona discharge between the needle-like electrodes 11, 12, and 13 is composed of, for example, a metal plate supported by a casing (not shown), and the needle-like electrodes 11, 12, and 13 are Each has a circular through-hole for penetrating.

The needle-like electrodes 11, 12, and 13 are arranged such that their tip portions are positioned at the centers of the circular through holes of the induction electrode 2 and the distance from the dielectric electrode 2 is equal. The needle-like electrodes 12 and 13 are located at the center of each circular through hole of the induction electrode 2 with the caps 51 and 52 being put on the respective tip portions.
Any of the needle-like electrodes 11, 12, 13 and the dielectric electrode 2 supported by the casing is electrically insulated from the casing.

The acicular electrodes 11, 12, 13 and the induction electrode 2 are connected to a high voltage generation circuit 3, and the high voltage generation circuit 3 applies a high voltage between the acicular electrodes 11, 12, 13 and the induction electrode 2. To do. When a high voltage is applied between the needle electrodes 11, 12, 13 and the induction electrode 2, corona discharge is generated due to the concentration of the electric field from the periphery of the through hole of the induction electrode 2 to the needle tip of the needle electrode 11. , Ions are generated. The generated ions are effectively released to the outside of the housing by the fan 4.
In addition, since each tip part is covered with caps 51 and 52 in needle-like electrodes 12 and 13, corona discharge does not occur, and corona discharge occurs only at the needle tip of needle-like electrode 11.

The caps 51 and 52 covering the tip portions of the needle electrodes 12 and 13 are configured to be removed from the needle electrodes 12 and 13 one by one by the discharge electrode selection means 6. The discharge electrode selection means 6 includes, for example, two rod-shaped members that respectively support the heads of the caps 51 and 52, and two solenoids that are respectively coupled to these rod-shaped members. When the caps 51 and 52 are removed from the needle-like electrodes 12 and 13, the discharge electrode selection means 6 pulls the caps 51 and 52 in a direction to remove the caps 51 and 52 from the needle-like electrodes 12 and 13.
Connected to the discharge electrode selection means 6 is a timer 7 for measuring the accumulated usage time from the start of use of the ion generator.

In the ion generator having such a configuration, when a power switch (not shown) is turned on, the high voltage generation circuit 3 applies a high voltage between the needle electrodes 11, 12, 13 and the induction electrode 2, and the fan 4 Is activated, and the timer 7 accumulates the time during which the power switch is turned on (discharge time).
When a high voltage is applied between the needle-like electrodes 11, 12, 13 and the induction electrode 2, a corona discharge is generated between the needle-like electrode 11 and the induction electrode 2, and ions are generated. The generated ions are released to the outside of the housing by the fan 4. In this case, no corona discharge occurs between the needle-like electrodes 12 and 13 and the induction electrode 2.

When the discharge time (operation time) accumulated by the timer 7 reaches a predetermined time (for example, one year), the discharge electrode selection means 6 removes the cap 51 that covers the needle electrode 12. Thereby, the acicular electrode 12 starts discharge, and the acicular electrode 12 is added to the electrode to discharge.
Thereafter, when the discharge time accumulated by the timer 7 further reaches a predetermined time (for example, one year), the discharge electrode selection means 6 removes the cap 52 that covers the needle electrode 13. Thereby, the acicular electrode 13 starts discharge, and the acicular electrode 13 is added to the electrode to discharge.

In the acicular electrode 11 whose discharge performance has deteriorated, the tip portion is worn out compared to the newly operated acicular electrodes 12 and 13, so that the amount of ions generated is inferior, but it is possible to continuously generate ions. . Therefore, every time the discharge electrode selection means 6 removes the caps 51 and 52 covering the needle-like electrodes 12 and 13, the amount of ion generation increases in the entire needle-like electrodes 11, 12 and 13.
Since the predetermined time for adding the discharge electrode varies depending on the design of the device, a period during which a predetermined amount of ion generation can be secured is measured in advance for each model, and is determined based on this.

(Embodiment 2)
FIG. 2 is a schematic diagram showing the main configuration of Embodiment 2 of the ion generator according to the present invention.
In this ion generator, the tip portions of the needle-shaped electrodes 11, 12, 13 are respectively covered with caps (discharge suppression members) 53, 51, 52, and in this state, the circular through-holes of the induction electrode 2 are formed. Located in the center.

  The caps 53, 51, 52 covering the tip portions of the needle electrodes 11, 12, 13 are configured to be removed from any one of the needle electrodes 11, 12, 13 by the discharge electrode selection means 6a. It has become. The discharge electrode selection means 6a includes, for example, three bar members that respectively support the heads of the caps 53, 51, and 52, and three solenoids that are respectively connected to these bar members.

When the caps 53, 51, 52 are removed from the needle-shaped electrodes 11, 12, 13, the discharge electrode selection means 6a causes the caps 53, 51, 52 to move to the needle-shaped electrodes 11, 12, 52 by passing a current through the solenoid. Pull in the direction to remove from 13. Further, when the caps 53, 51, 52 are covered with the needle-like electrodes 11, 12, 13, the discharge electrode selection means 6a causes the caps 53, 51, 52 to pass through the solenoids by passing a current through the solenoid. , 12 and 13 are pushed in the direction of covering.
The discharge electrode selection means 6a is connected with a timer 7 for measuring the accumulated usage time from the start of use of the ion generator. Other configurations are the same as those of the above-described first embodiment (FIG. 1), and therefore, the same portions are denoted by the same reference numerals and description thereof is omitted.

  In the ion generator having such a configuration, when a power switch (not shown) is turned on, the high voltage generation circuit 3 applies a high voltage between the needle electrodes 11, 12, 13 and the induction electrode 2, and the fan 4 Is activated, and the timer 7 accumulates the time during which the power switch is turned on (discharge time). When used for the first time, the discharge electrode selection means 6 a removes the cap 53 from the needle electrode 11 and covers the caps 51 and 52 on the needle electrodes 12 and 13.

When a high voltage is applied between the needle-like electrodes 11, 12, 13 and the induction electrode 2, a corona discharge is generated between the needle-like electrode 11 and the induction electrode 2, and ions are generated. The generated ions are released to the outside of the housing by the fan 4. In this case, no corona discharge occurs between the needle-like electrodes 12 and 13 and the induction electrode 2.
In this state, even when the power switch is turned on again after the power switch is turned off, the timer 7 and the discharge electrode selection means 6a operate in the same manner as described above.

  When the discharge time (operation time) accumulated by the timer 7 reaches a predetermined time (for example, one year), the discharge electrode selection means 6a covers the cap 53 on the needle electrode 11 and the cap 51 is needle-shaped. Remove from electrode 12. Thereby, the acicular electrode 12 starts discharge, and the acicular electrode 12 is selected as an electrode to discharge. Further, the ion generation amount returns to the initial state.

In this state, even when the power switch is turned on again after the power switch is turned off, the timer 7 and the discharge electrode selection means 6a operate in the same manner as described above.
After that, when the discharge time accumulated by the timer 7 reaches a predetermined time (for example, one year), the discharge electrode selection means 6a covers the cap 51 on the needle electrode 12 and the cap 52 covers the needle electrode. Remove from 13. Thereby, the acicular electrode 13 starts discharge, and the acicular electrode 13 is selected as an electrode to discharge. Further, the ion generation amount returns to the initial state.

In this ion generator, since the needle-like electrode whose discharge performance has deteriorated stops discharging and the new needle-like electrode starts discharging every predetermined time, the fluctuation range of the ion generation amount is small, and the ion generation amount is small. Stabilize.
Since the predetermined time for switching the discharge electrode varies depending on the design of the device, a period during which a predetermined amount of ion generation can be secured is measured in advance for each model, and is determined based on this.

(Embodiment 3)
FIG. 3 is a schematic diagram showing the main configuration of Embodiment 3 of the ion generator according to the present invention.
In this ion generator, the caps 51 and 52 covering the tip portions of the needle electrodes 12 and 13 are removed from the needle electrodes 12 and 13 one by one by the discharge electrode selection means 6b. . The discharge electrode selection means 6b includes, for example, two rod-shaped members that respectively support the heads of the caps 51 and 52, and two solenoids that are respectively coupled to these rod-shaped members.

When the caps 51 and 52 are removed from the needle-like electrodes 12 and 13, the discharge electrode selection means 6 b pulls the caps 51 and 52 in a direction to remove the caps 51 and 52 from the needle-like electrodes 12 and 13.
An ion sensor 8 that detects the amount of ions (for example, [pieces / cm ³ ]) generated by the ion generator is connected to the discharge electrode selection means 6b instead of the timer 7. Other configurations are the same as those of the above-described first embodiment (FIG. 1), and therefore, the same portions are denoted by the same reference numerals and description thereof is omitted.

In the ion generator having such a configuration, when a power switch (not shown) is turned on, the high voltage generation circuit 3 applies a high voltage between the needle electrodes 11, 12, 13 and the induction electrode 2, and the fan 4 And the ion sensor 8 operates.
When a high voltage is applied between the needle-like electrodes 11, 12, 13 and the induction electrode 2, a corona discharge is generated between the needle-like electrode 11 and the induction electrode 2, and ions are generated. The generated ions are released to the outside of the housing by the fan 4. In this case, no corona discharge occurs between the needle-like electrodes 12 and 13 and the induction electrode 2. The ion sensor 8 detects the amount of generated ions.

  The discharge electrode selection means 6b periodically reads the ion amount detected by the ion sensor 8, calculates a moving average of the read ion amount a predetermined number of times, for example, and determines whether the calculated moving average is smaller than the predetermined amount. judge. The discharge electrode selection means 6b removes the cap 51 that covers the needle electrode 12 when the calculated moving average is smaller than a predetermined amount. Thereby, the acicular electrode 12 starts discharge, the acicular electrode 12 is added to the electrode to be discharged, and the reduced ion generation amount is restored.

Thereafter, the discharge electrode selecting means 6b removes the cap 52 that covers the needle electrode 13 when it is determined that the moving average of the ion amount decreases and the calculated moving average is smaller than the predetermined amount again. Thereby, the acicular electrode 13 starts discharging, the acicular electrode 13 is added to the discharging electrode, and the reduced ion generation amount is restored. Other operations are the same as the operations of the first embodiment described above, and thus description thereof is omitted.
In addition, in this Embodiment 3, although the case where a needle-shaped electrode is comprised by three is shown, the needle-shaped electrode may be comprised by what number, and the ion which became stable over a long period as the number increased. The generation performance can be maintained.

(Embodiment 4)
FIG. 4 is a schematic diagram showing the main configuration of Embodiment 4 of the ion generator according to the present invention.
In this ion generator, the tip portions of the needle-like electrodes 11, 12, 13 are covered with caps (discharge suppression members) 53, 51, 52, respectively.
The caps 53, 51, 52 covering the tip portions of the needle electrodes 11, 12, 13 are configured to be removed from any one of the needle electrodes 11, 12, 13 by the discharge electrode selection means 6c. It has become. The discharge electrode selection means 6c includes, for example, three bar members that respectively support the heads of the caps 53, 51, and 52, and three solenoids that are respectively connected to these bar members.

When the caps 53, 51, 52 are removed from the needle-like electrodes 11, 12, 13, the discharge electrode selection means 6c causes the caps 53, 51, 52 to be brought into contact with the needle-like electrodes 11, 12, 52 by passing a current through the solenoid. Pull in the direction to remove from 13. Further, when the caps 53, 51, 52 are covered with the needle-like electrodes 11, 12, 13, the discharge electrode selecting means 6c causes the caps 53, 51, 52 to pass through the solenoids by passing the current through the solenoid. , 12 and 13 are pushed in the direction of covering.
An ion sensor 8 for detecting the amount of ions (for example, [pieces / cm ³ ]) generated by the ion generator is connected to the discharge electrode selection means 6 c instead of the timer 7. Other configurations are the same as those of the above-described second embodiment (FIG. 2), and thus the same portions are denoted by the same reference numerals and description thereof is omitted.

  In the ion generator having such a configuration, when a power switch (not shown) is turned on, the high voltage generation circuit 3 applies a high voltage between the needle electrodes 11, 12, 13 and the induction electrode 2, and the fan 4 And the ion sensor 8 operates. When used for the first time, the discharge electrode selection means 6 c removes the cap 53 from the needle electrode 11 and covers the caps 51 and 52 on the needle electrodes 12 and 13.

  When a high voltage is applied between the needle-like electrodes 11, 12, 13 and the induction electrode 2, a corona discharge is generated between the needle-like electrode 11 and the induction electrode 2, and ions are generated. The generated ions are released to the outside of the housing by the fan 4. In this case, no corona discharge occurs between the needle-like electrodes 12 and 13 and the induction electrode 2. The ion sensor 8 detects the amount of generated ions.

  The discharge electrode selection means 6c periodically reads the ion amount detected by the ion sensor 8, calculates a moving average of the read ion amount a predetermined number of times, for example, and determines whether the calculated moving average is smaller than the predetermined amount. judge. When the calculated moving average is smaller than the predetermined amount, the discharge electrode selection means 6 c covers the cap 53 on the needle electrode 11 and removes the cap 51 from the needle electrode 12. Thereby, the acicular electrode 12 starts discharge, and the acicular electrode 12 is selected as an electrode to discharge. Further, the ion generation amount returns to the initial state.

Thereafter, when the moving average of the ion amount decreases and the discharge electrode selecting means 6c determines that the calculated moving average is smaller than the predetermined amount again, the cap 51 is covered with the needle electrode 12, and the cap 52 Is removed from the needle electrode 13. Thereby, the acicular electrode 13 starts discharge, and the acicular electrode 13 is selected as an electrode to discharge. Further, the ion generation amount returns to the initial state. Other operations are the same as the operations of the second embodiment described above, and thus the description thereof is omitted.
In the fourth embodiment, a case is shown in which the needle-shaped electrode is composed of three. However, the needle-shaped electrode may be composed of any number of ions, and as the number of the needle-shaped electrode is increased, stable ions are obtained over a long period of time. The generation performance can be maintained.

(Embodiment 5)
FIG. 5 is a cross-sectional view schematically showing a main configuration of a discharge device according to Embodiment 5 of the present invention, and FIG. 6 is a perspective view showing the discharge device shown in FIG. 5 in a perspective view.
In this discharge device, a high voltage generating circuit 102, a needle-like electrode (needle-like discharge electrode) 103, a movable plate 104, electric wires 105 and 106, an electrode fixing base 107, a counter electrode (dielectric electrode) are provided in a rectangular parallelepiped casing 101. 108, an electrode cover (covering portion) 109, and an ion emission opening 110 are disposed.

The electrode fixing base 107 is fixed to the housing 101 side, and three needle-like electrodes 103 are attached to the electrode fixing base 107 at regular intervals in one direction. The needle electrode 103 is connected to the high voltage generation circuit 102 by an electric wire 105.
The movable plate 104 covers the window 112 provided at the center of the surface of the housing 101 facing the needle electrode 103 from the inside, and is slidable in the parallel direction of the needle electrode 103. It is inserted into a nearby suspension mechanism (not shown). The movable plate 104 can be slid manually or by driving means such as a motor (not shown). A handle 111 for manually sliding the movable plate 104 is attached to the surface of the movable plate 104 on the window 112 side.

  On the movable plate 104, two electrode covers 109, one ion emission opening 110, and two electrode covers 109 are arranged in parallel in the sliding direction in this order. The electrode cover 109 protrudes from the inner surface of the movable plate 104. Any one of the needle-like electrodes 103 is opposed to the ion emission opening 110, and the remaining two needle-like electrodes 103 are respectively covered with any two of the electrode covers 109. Has been.

Inside the movable plate 104, a counter electrode 108 is provided in a U shape so as to surround each tip portion of the three needle-like electrodes 103 independently of the movable plate 104. The counter electrode 108 is connected to the high voltage generation circuit 102 by an electric wire 106.
The electrode cover 109 covers the tip portion of the needle electrode 103. In this case, the electrode cover 109 is configured so that the electric charge released from the tip portion of the needle electrode 103 adheres to the inner surface of the electrode cover 109 and the potential difference between the tip portion of the needle electrode 103 and the electrode cover 109 becomes small. It is comprised with the insulator or the dielectric material.

FIG. 7 is a perspective view showing a configuration example of the movable plate 104, and is shown in the opposite direction to FIG. 6 for convenience.
Each of the electrode covers 109 protrudes from one surface of the movable plate 104 (inner surface side of the housing 101), and a groove for inserting the needle electrode 103 is provided in the sliding direction of the movable plate 104, respectively. It has been.
The electrode cover 109 is made of an insulator or a dielectric as described above, and a high voltage is applied to the needle electrode 103 in a state where the tip of the needle electrode 103 exists in these grooves, When a slight discharge occurs, the inner surface of the groove of the electrode cover 109 is charged.

The acicular electrode 103 not covered with the electrode cover 109 faces the ion emission opening 110. Since the needle-like electrode 103 is not covered with the electrode cover 109, the needle-like electrode 103 is discharged by an electric field generated between the counter electrode 108. Ions, radicals, and the like generated by this discharge are efficiently released from the ion emission opening 110 to the external space.
The ion emission opening 110 does not necessarily have a circular shape as illustrated, and may have any shape such as a square or a triangle.

  The insulator or dielectric material of the electrode cover 109 is preferably a material such as plastic, rubber, or ceramic. Moreover, it is good also as a material which has elasticity so that even if it contacts the front-end | tip part of the acicular electrode 103, a front-end | tip part is not destroyed. In addition, an elastic material may be in contact with the vicinity of the tip portion of the needle electrode 103 so that dust attached to the tip portion of the needle electrode 103 can be removed. In this case, it is possible to clean the tip of the needle electrode 103 by sliding the movable plate 104.

  In the discharge device having such a configuration, when a power supply switch (not shown) is turned on and a high voltage is applied between the needle electrode 103 and the counter electrode 108 by the high voltage generation circuit 102 and is used for the first time, the movable plate 104 is used. For example, in FIG. 5, the position is moved to the rightmost side in the sliding direction. As a result, as shown in FIG. 5, the right needle-like electrode 103 faces the ion emission opening 110 and is discharged by the electric field generated between the counter electrode 108. Ions, radicals, and the like generated by this discharge are efficiently released from the ion emission opening 110 to the external space.

On the other hand, in FIG. 5, the tip portions of the middle and left needle-like electrodes 103 are present in the grooves of the electrode cover 109, respectively, and when a high voltage is applied to the needle-like electrodes 103 and a slight discharge occurs. The inner surface of the groove of the electrode cover 109 is charged, and the voltage between the tip of the needle electrode 103 and the electrode cover 109 decreases. For this reason, the discharge from the needle electrode 103 is suppressed, and the deterioration of the needle electrode 103 is suppressed.
In the state described above, when the movable plate 104 is slid a plurality of times in the left-right direction manually or by driving means such as a motor (not shown) periodically, for example, every few weeks, each tip portion of the needle electrode 103 is cleaned. be able to.

  After using the discharge device in the above-described state, for example, for half a year or one year, the movable plate 104 is manually or by driving means such as a motor (not shown) in FIG. Keep it close. As a result, the middle needle-like electrode 103 is opposed to the ion emission opening 110 and is discharged by the electric field generated between the counter electrode 108. Ions, radicals, and the like generated by this discharge are efficiently released from the ion emission opening 110 to the external space.

On the other hand, in FIG. 5, the tip portions of the left and right needle-like electrodes 103 are present in the grooves of the electrode cover 109, respectively, and when a high voltage is applied to the needle-like electrode 103 and a slight discharge occurs. The inner surface of the groove of the electrode cover 109 is charged, and the voltage between the tip of the needle electrode 103 and the electrode cover 109 decreases. For this reason, the discharge from the needle electrode 103 is suppressed, and the deterioration of the needle electrode 103 is suppressed.
In this state, when the movable plate 104 is slid a plurality of times in the left-right direction manually or by driving means such as a motor (not shown) periodically, for example, every few weeks, each tip portion of the needle electrode 103 is cleaned. Can do.

  After using this discharge device in the above-described state, for example, for another half year or one year, the movable plate 104 is manually or by drive means such as a motor not shown in FIG. Move to the left. As a result, the left needle-like electrode 103 faces the ion emission opening 110 and is discharged by the electric field generated between the counter electrode 108. Ions, radicals, and the like generated by this discharge are efficiently released from the ion emission opening 110 to the external space.

On the other hand, in FIG. 5, the tip portions of the middle and right needle-like electrodes 103 are present in the grooves of the electrode cover 109, respectively, and when a high voltage is applied to the needle-like electrodes 103 and a slight discharge occurs. The inner surface of the groove of the electrode cover 109 is charged, and the voltage between the tip of the needle electrode 103 and the electrode cover 109 decreases. For this reason, the discharge from the needle electrode 103 is suppressed, and the deterioration of the needle electrode 103 is suppressed.
In this state, when the movable plate 104 is slid a plurality of times in the left-right direction manually or by driving means such as a motor (not shown) periodically, for example, every few weeks, each tip portion of the needle electrode 103 is cleaned. Can do.

(Embodiment 6)
FIG. 8: is a perspective view which shows perspectively the principal part structure of Embodiment 6 of the discharge device which concerns on this invention.
This discharge device includes a rectangular parallelepiped housing 101a, needle-like electrodes (needle-like discharge electrodes) 103a and 103b, a movable plate 104a, a counter electrode (dielectric electrode) 108a, an electrode cover (covering portion) 109, and an ion emission device. Openings 110a and 110b and a high voltage generation circuit (not shown) are arranged.

The needle-like electrodes 103a and 103b are fixed to the housing 101a side, and two of them are arranged in parallel at the same interval and attached in one direction. The needle-like electrodes 103a and 103b are connected to a high voltage generation circuit (not shown), and are applied with high voltages having opposite polarities.
The movable plate 104a is slidable in the parallel direction of the needle electrodes 103a and 103b so as to close the window 112a provided on the surface of the housing 101a facing the needle electrodes 103a and 103b from the inside. The housing 101a is inserted into two through holes 113 provided on opposite side walls. The movable plate 104a can be slid manually or by driving means such as a motor (not shown). In the case of manual operation, the end of the movable plate 104a formed so as to protrude from the housing 101a is pressed or pulled. And slide.

  The movable plate 104a has a row of electrode covers 109, an ion emission opening 110a and an electrode cover 109 arranged in parallel in a sliding direction, and a row of electrode covers 109, an ion emission opening 110b and an electrode cover 109. Are provided in parallel. The electrode cover 109 protrudes from the inner surface of the movable plate 104a. Any one of the needle-like electrodes 103a and 103b is opposed to each of the ion emission openings 110a and 110b, and each of the remaining ones of the needle-like electrodes 103a and 103b is any one of the electrode covers 109. Each is configured to be covered by one piece.

Inside the movable plate 104a, an opposing electrode 108a is provided in an E-shape so as to surround the tip portions of the two rows of needle-like electrodes 103a and 103b independently of the movable plate 104a. The counter electrode 108a is connected to a ground terminal of a high voltage generation circuit (not shown).
The electrode cover 109 covers the tip portions of the needle electrodes 103a and 103b. In this case, the electric charges released from the tip portions of the needle-like electrodes 103a and 103b adhere to the inner surface of the electrode cover 109, so that each potential difference between the tip portions of the needle-like electrodes 103a and 103b and the electrode cover 109 becomes small. The electrode cover 109 is made of an insulator or a dielectric.

Similarly to the case shown in FIG. 7, the electrode cover 109 protrudes from one surface of the movable plate 104a (the inner surface side of the housing 101a), and in the sliding direction of the movable plate 104a, the needle electrode 103a. , 103b are respectively provided with grooves.
The electrode cover 109 is made of an insulator or a dielectric as described above, and the needle electrodes 103a and 103b are positively connected to the needle electrodes 103a and 103b in a state where the tip portions of the needle electrodes 103a and 103b are present in these grooves, respectively. When a high voltage of negative polarity and negative polarity are respectively applied and a slight discharge occurs, the inner surface of the groove of each electrode cover 109 is charged.

The needle-like electrodes 103a and 103b that are not covered with the electrode cover 109 are opposed to the ion emission openings 110a and 110b, respectively. Since these needle-like electrodes 103a and 103b are not covered with the electrode cover 109, they are each discharged by each electric field generated between them and the counter electrode 108a. Positive and negative ions, radicals, and the like generated by these discharges are efficiently released from the ion emission openings 110a and 110b to the external space.
The ion emission openings 110a and 110b do not necessarily have a circular shape as illustrated, and may have any shape such as a quadrangle or a triangle.

  The insulator or dielectric material of the electrode cover 109 is preferably a material such as plastic, rubber, or ceramic. Moreover, it is good also as a material which has elasticity so that even if it contacts the front-end | tip part of the acicular electrodes 103a and 103b, a front-end | tip part is not destroyed. Moreover, it is good also as a structure which the material which has elasticity contacts the vicinity of the front-end | tip part of needle-like electrode 103a, 103b so that the dust adhering to the front-end | tip part of needle-like electrode 103a, 103b can be removed. In this case, it is possible to clean the tip portions of the needle-like electrodes 103a and 103b by sliding the movable plate 104a.

  In the discharge device having such a configuration, a power switch (not shown) is turned on, and positive and negative high voltages are respectively applied between the needle electrodes 103a and 103b and the counter electrode 108a by a high voltage generation circuit. When first used, the movable plate 104a is set so that one of the needle-like electrodes 103a and 103b faces the ion emission openings 110a and 110b, respectively. Thereby, one needle-like electrode 103a, 103b is each discharged by each electric field generated between the counter electrodes 108. Positive and negative ions, radicals, and the like generated by these discharges are efficiently released from the ion emission openings 110a and 110b to the external space.

On the other hand, the tip portions of the other needle-like electrodes 103a and 103b are present in the grooves of the electrode cover 109, respectively, and positive and negative high voltages are applied to the needle-like electrodes 103a and 103b to cause slight discharge. When this occurs, the inner surface of the groove of the electrode cover 109 is charged, and the voltage between the tip portions of the needle-like electrodes 103a and 103b and the electrode cover 109 decreases. For this reason, each discharge of the other acicular electrodes 103a and 103b is suppressed, and the deterioration of the acicular electrodes 103a and 103b is suppressed.
In the above-described state, when the movable plate 104a is reciprocally slid a plurality of times manually or by a driving means such as a motor (not shown) periodically, for example, every few weeks, the tip portions of the needle electrodes 103a and 103b are cleaned. And deterioration of the needle-like electrodes 103a and 103b can be suppressed.

  In this state, after this discharge device is used, for example, for half a year or one year, the other needle-like electrodes 103a and 103b are used for ion emission by manually or by driving means such as a motor (not shown). It sets so that it may each oppose to opening part 110a, 110b. As a result, the other non-degraded needle-like electrodes 103a and 103b start to be discharged by the respective electric fields generated between the counter electrodes 108, and the discharge efficiency returns to the value at the start of use. Positive and negative ions, radicals, and the like generated by these discharges are efficiently released from the ion emission openings 110a and 110b to the external space.

On the other hand, the tip portions of one of the needle-like electrodes 103a and 103b are present in the grooves of the electrode cover 109, respectively, and positive and negative high voltages are applied to the needle-like electrodes 103a and 103b to cause slight discharge. When this occurs, the inner surface of the groove of the electrode cover 109 is charged, and the voltage between the tip portions of the needle-like electrodes 103a and 103b and the electrode cover 109 decreases. For this reason, each discharge of one acicular electrode 103a, 103b is suppressed, and deterioration of acicular electrode 103a, 103b is each suppressed.
In the above-described state, when the movable plate 104a is reciprocally slid a plurality of times manually or by a driving means such as a motor (not shown) periodically, for example, every few weeks, the tip portions of the needle electrodes 103a and 103b are cleaned. And deterioration of the needle-like electrodes 103a and 103b can be suppressed.

  In Embodiments 5 and 6 described above, the movable plate is slid. However, the movable plate may be provided so as to be rotatable about an axis fixed to the housing side. In this case, the electrode cover and the ion emission opening are provided on the same rotation circumference of the movable plate, and the needle-like electrodes are arranged on the same circumference and fixed to the housing side so as to correspond to them. Thereby, the needle electrode to be discharged can be selected by rotating the movable plate.

2 Induction electrode 3 High voltage generation circuit 6, 6a, 6b, 6c Discharge electrode selection means 7 Timer 8 Ion sensor (detector)
11, 12, 13 Needle-like electrode (needle-like discharge electrode)
51, 52, 53 Cap (Discharge suppression member)
101, 101a Case 102 High voltage generation circuit 103, 103a, 103b Needle-like electrode (needle-like discharge electrode)
104, 104a Movable plate 107 Electrode fixing base 108, 108a Counter electrode (dielectric electrode)
109 Electrode cover (cover)
110, 110a, 110b Ion emission opening 111 Handle 112, 112a Window

Claims (12)

In an ion generator that generates ions by applying a voltage between a needle-like discharge electrode and a dielectric electrode to cause discharge,
A plurality of acicular discharge electrodes, an insulating discharge inhibiting member that individually covers the distal end portions of the acicular discharge electrodes, and removing the discharge inhibiting member from the distal end portion of the acicular discharge electrode; An ion generator comprising: discharge electrode selection means for selecting a needle-like discharge electrode to be discharged.   The ion generator according to claim 1, wherein the discharge suppressing member is a cap that covers a tip portion of the acicular discharge electrode.   The ion generator according to claim 1 or 2, wherein each tip portion of the plurality of needle-like discharge electrodes has the same distance from the dielectric electrode.   A timer for accumulating the operation time is further provided, and each time the timer measures a predetermined time, the discharge electrode selection means is configured to remove one of the discharge suppression members from the tip portion of the needle-like discharge electrode. The ion generator as described in any one of Claim 1 to 3.   A detector for detecting the amount of generated ions, and means for determining whether or not the amount of ions detected by the detector is smaller than a predetermined amount, and when the means is determined to be smaller than a predetermined amount, The ion generator according to any one of claims 1 to 3, wherein the discharge electrode selection means is configured to remove one of the discharge suppression members from the tip portion of the needle-like discharge electrode.   The discharge electrode selection means is configured such that when one of the discharge suppression members is removed from the tip portion of the needle-like discharge electrode, the tip portion of another selected needle-like discharge electrode is covered with the discharge suppression member. The ion generator according to claim 4 or 5. In the discharge device that discharges by applying a voltage between the acicular discharge electrode and the dielectric electrode inside the housing,
A plurality of the needle-like discharge electrodes, a covering portion for covering the tip portion of the needle-like discharge electrode, and a movable plate having an opening for allowing the tip portion of the needle-like discharge electrode to be viewed from the housing, By moving the movable plate, the tip portion of the acicular discharge electrode is covered with the covering portion or viewed from the opening, and the acicular discharge electrode to be discharged is selected. Discharge device.   The discharge device according to claim 7, wherein the covering portion is made of an insulator.   The voltage is alternating current or direct current whose average value is not 0, and the needle-like discharge electrode whose tip portion is coated on the covering portion is charged by the voltage on the surface of the covering portion on the tip portion side, The discharge device according to claim 7 or 8, wherein the discharge device is configured to suppress discharge.   The discharge device according to any one of claims 7 to 9, wherein the movable plate is fitted into the housing so as to be slidable in a plate surface direction.   The discharge device according to any one of claims 7 to 9, wherein the movable plate is pivotally attached to the casing so as to be rotatable in a plate surface direction.   The discharge device according to claim 10 or 11, wherein the covering portion is configured to come into contact with a tip portion of a needle-like discharge electrode when the movable plate slides or rotates in a plate surface direction.

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