KR101658676B1 - Ion generator - Google Patents

Abstract

Even when the air ions are guided to the member requiring the static elimination by the conduit, the effect of removing the static electricity is improved. The ion generating flow path 15 is formed in the inside of the discharge unit 11 and the air supplied from the air-supplying port 22 to the ion generating unit 15 is supplied to the discharge electrode 16 and the opposite electrode 13 Ionized by the corona discharge caused by the corona discharge. Air ions are emitted to the outside at the tip portion of the discharge unit 11. [ An air inlet 27 for introducing outside air to the air ions generated through the ion generation flow path 15 is formed in the tip portion of the discharge unit and the outside air introduced by the ejector is added to the air ions.

Description

[0001] ION GENERATOR [0002]

The present invention relates to an ion generating device for spraying air ions generated by ionizing air using a corona discharge onto a member requiring electrostatic elimination through a conduit.

An ion generating device such as an ionizer or a static eliminator for removing static electricity by spraying air ions on a member requiring static elimination is used in using a member charged with static electricity which requires static elimination. Ion production devices used in production sites for the fabrication and assembly of electronic components have been used to remove static charges charged to components requiring electrostatic removal, such as electronic components and manufacture-assembly-jigs. Spraying air ions to members requiring static elimination can prevent foreign substances from attaching to electronic parts or the like due to static electricity, and can prevent damage to electronic parts due to static electricity or attaching to the jig.

As disclosed in Patent Documents 1-3 (Japanese Patent Application Laid-Open Nos. 2000-138090, 2004-228069 and 2006-40860), air is supplied from the outside to needle-shaped discharge electrodes, and high frequency An ion generating device is used in an application example in which a high voltage is applied and a corona discharge is generated in a discharge electrode to ionize the air.

Patent Documents 2 and 3 disclose an ion generating device for directing ionized air ions to a member requiring removal of static electricity and directly spraying air ions from a nozzle assembled with the discharge electrode to a member requiring static elimination. In the ion generating apparatus disclosed in Patent Document 2, the discharge electrode is located inside the nozzle by retracting the discharge electrode from the nozzle tip. Patent Document 3 discloses an ion generating apparatus in which a discharge electrode protrudes from a nozzle tip. On the other hand, in the ion generating device disclosed in Patent Document 1, air ions are guided through a conduit to a member located away from the ion generating device and requiring removal of static electricity.

As disclosed in Patent Documents 2 and 3, when air ions are spouted out from a nozzle constituting an opposite electrode and a discharge electrode is coupled to the inside thereof, air ions are sprayed on a member requiring static elimination, The ions can be sprayed onto the member requiring electrostatic elimination prior to neutralization of the air ions. On the contrary, when air ions are guided to a member requiring static elimination by a conduit attached to the nozzle as shown in Patent Document 1, air ions will be neutralized before they reach a member requiring static elimination, There arises a problem that the effect can not be sufficiently achieved.

It is an object of the present invention to improve the electrostatic removing effect even when air ions are guided to a member requiring electrostatic elimination by conduction.

A discharge electrode and an opposite electrode provided opposite to the discharge electrode and generating a corona discharge by applying a high alternating current across the discharge electrode and the opposite electrode to produce air ions The ion generating device includes a discharging unit including a discharging electrode, an opposite electrode, and an ion generating flow path formed inside the discharging unit; And an air supply unit disposed at a base end portion of the discharge unit and having an air supply port communicating with the ion generation flow path and supplying compressed air to the ion generation flow path, And an ejector for introducing outside air from the air inlet to the air ions passing through the ion generation flow path is provided at the downstream side of the air inlet located at the tip portion of the discharge unit To an ion generating device provided.

In the ion generating device according to the present invention, the discharge electrode is coaxially arranged at the center of the ion generation flow path. In the ion generating device according to the present invention, the discharge electrodes are arranged in a direction across the ion production flow path. In the ion generating device according to the present invention, a discharge port is provided at the base end of the discharging unit, and the suction port sucks the outside air by the air blown out from the air-supplying port toward the ion generating flow path, Into the flow path. In the ion generating apparatus according to the present invention, the tip portion of the discharging unit has an auxiliary air inlet, and the auxiliary air inlet supplies external air to the air ions obtained after the air flow from the air inlet is added to the air ions do. In the ion generating device according to the present invention, the inner diameter of the air discharge port of the discharge unit is larger than the inner diameter of the ion generation flow path. In the ion generating apparatus according to the present invention, the conduit for guiding the air ions emitted from the discharge unit to the member requiring the electrostatic elimination is mounted on the tip portion of the discharge unit.

According to the present invention, the air ions are generated by ionizing the air supplied into the ion generation flow path using a corona discharge generated around the discharge electrode, and using an ejector for obtaining an ejecting effect from the air inlet, Ions. Thus, without increasing the amount of compressed air supplied from the air inlet to the ion producing flow path, air from the air inlet is added to the air ions, and a combination of air and air ions can be supplied to the conduit. Therefore, a large amount of air ions can be supplied to the member requiring removal of static electricity from the conduit, and the static electricity charged in the member requiring static elimination can be quickly removed (discharged). Also, since the external air, which may include foreign matter, is not sprayed on the tip of the discharge electrode, the ion balance can be improved without decreasing the ion balance due to the foreign substance, and thereby the static electricity can be reliably removed have.

1 is a cross-sectional view of an ion generating device according to an embodiment of the present invention.
2 is a cross-sectional view of an ion generating device according to another embodiment of the present invention.
3 is a cross-sectional view of an ion generating device according to another embodiment of the present invention.
4 is a cross-sectional view of an ion generating device according to another embodiment of the present invention.
5 is a cross-sectional view of an ion generating device according to a comparative example.
6 is a cross-sectional view of an ion generating device according to another comparative example.
FIG. 7 is a characteristic line diagram showing an effect of removing static electricity in the ion generating device according to the present invention and the ion generating device according to the comparative example in FIG. 5;
FIG. 8 is a graph showing the result of disturbance of the ion balance due to the forced injection of the fine particles into the ion generating field according to the ion generating device according to the present invention and the comparative example of FIG. 6.
FIG. 9 is a characteristic line diagram showing the ion balance effect of the ion generating device according to the present invention and the ion generating device according to the comparative example of FIG. 6;
10 is a cross-sectional view of an ion generating device according to an embodiment of the present invention.
11 is a cross-sectional view of an ion generating device according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. The ion generating device 10a shown in Fig. 1 has a discharge unit 11 and an air supply unit 12 disposed at a base end portion of the discharge unit 11 and made of an insulator. The discharge unit 11 includes an opposite electrode 13 made of a conductive material and a cylindrical insulating member 14 mounted inside the opposite electrode. An ion generating flow path (15) is formed inside the insulating member (14). A rod-like discharge needle, i.e., a discharge electrode 16, made of a conductive material, is arranged inside the ion generating flow path 15 and located at the center thereof. The proximal end of the discharge electrode 16 is attached to the air supply unit 12 and the tip portion of the discharge electrode 16 protrudes into the ion generation flow path 15 in the air supply unit 12, Coaxial with the flow path. Thus, the discharge unit 11 has the discharge electrode 16 located inside the ion generation flow path 15 and the opposing electrode 13 opposing the discharge electrode.

The discharge electrode 16 and the opposite electrode 13 are connected to the power supply unit 17 and a high voltage of AC from the power supply unit 17 is applied across the discharge electrode 16 and the opposite electrode 13, . A non-uniform electric field is generated around the sharp end of the discharge electrode 16, and a high voltage alternating current of, for example, a voltage of 6 kV and a frequency of 70 kHz is supplied from the power supply unit 17 across the electrodes. A discharge occurs at the end portion thereof. When a high voltage of the anode is applied to the discharge electrode 16, since the discharge electrode 16 absorbs the electrons of the air near the discharge electrode, the air in the vicinity thereof becomes ions having a positive electric charge. In contrast, when a high voltage of the cathode is applied to the discharge electrode 16, electrons are discharged from the discharge electrode 16, so that the air in the vicinity thereof becomes ions having a negative polarity.

The air supply unit 12 is formed with a supply port 21 to which a supply hose A for supplying air from the compression-air pressure source 20 is connected. The supply port 21 is open toward the ion generation flow path 15 and communicates with a plurality of air-supply ports 22 formed in the air supply unit 12. Air supplied from the compressed-air pressure source 20 to the ion generation flow path 15 through the air-supply ports 22 is supplied to the ion generating flow path 15 through the corona It is ionized by discharge and becomes air ions.

The tip portion of the discharge unit 11 made of an insulating material or metal such as rayon acts as a nozzle 23 and air ions are emitted from the air discharge port 19 of the nozzle 23 tip. A conduit 24 for guiding the air ions to the member requiring static elimination is mounted on the tip portion of the nozzle 23. This conduit 24 is made of a lace, such as chloroethylene, and is formed of a flexible, insulative tube. The inner diameter D is about 8 mm, and the length L is about 100 to 500 mm or more.

If the ion generating flow path 15 formed by the insulating member 14 and the counter electrode 13 has an inner diameter d, the inner diameter D of the air discharge port 19 in the nozzle 23 and the inner diameter D of the conduit 24 D is determined to be larger than the inner diameter of the ion generation flow path 15, respectively. The nozzle 23 gradually increases in the constricted portion 25 having an inner diameter equal to or larger than the inner diameter d of the ion generation flow path 15 and the inner diameter toward the inner surface of the conduit 24, And a tapered face 26 that is tip side formed from the tip 25 side. The nozzle 23 is formed with a plurality of air inlets 27 for supplying outside air to the air ions generated in the ion generation flow path 15 as indicated by an arrow B in the drawing. The nozzle 23 is formed with an arc face 28 for guiding the air introduced from the air inlets 27 to the contraction portion 25 side. The contraction portion 25, the tapered surface 26 and the arc surface 28 constitute an ejector 29, which passes through the ion generation flow path 15 and flows through the air ions flowing inside the nozzle 23 To guide the outside air from the air inlets (27).

The tapered surface 26 formed in the nozzle 23 has a diffuser function and external air from the air inlets 27 is introduced into the conduit 24 through the air outlet port 19 in the nozzle 23. [ do. Thus, the air supplied to the ion producing flow path 15 in the air-supplying ports 22 is ionized, the outside air introduced from the air inlets 27 is added, and the combination of the ionized air and the outside air And is supplied into the conduit 24. As described above, since the ejector 29 is provided on the nozzle 23, even if the flow rate of the compressed air supplied to the supply port 21 is reduced, the air sprayed to the member requiring the static elimination from the tip of the conduit 24 The amount of ions is not so reduced, and neutralization due to collisions of anions and cations can be reduced. Therefore, the static electricity charged in the member requiring static elimination can be removed in a short time.

A plurality of suction ports 31 are provided at the base end of the discharge unit 11 and air is spouted out toward the ion generation flow path 15 as indicated by the arrow C, (22). Therefore, air supplied externally through the intake ports 31 is added to the air ions, without increasing the flow rate of the air supplied from the air-supply ports 22 to the ion generation flow path 15, A large amount of air is supplied to the ion generation flow path 15. As described above, since the air from the suction ports 31 is added to the air ions together with the compressed air supplied to the supply port 21, even if the flow rate of the compressed air supplied to the supply port 21 is reduced, Can be prevented from adhering to the tip of the discharge electrode (16). Particularly, the air ejected from the air-supplying pods 22 mainly flows through the central portion of the ion generation flow path 15 to cover the discharge electrode 16 and the external air supplied from the suction ports 31 is mainly generated by ion generation Flows along the outer circumferential portion of the flow path 15 so that even when fine air particles are contained in the air supplied from the outside through the suction ports 31 as clean air is ejected from the air- It is possible to reliably prevent the foreign matter from adhering to the discharge electrode 16, and the balance of the ions can be improved.

Since the air introduced from the air inlets 27 by the ejector 29 is collected and passed on the downstream side of the discharge electrode 16, the air inlets 27 Is introduced. Therefore, the ion balance of the air ions ejected from the conduit 24 is improved, and thus the electrostatic elimination effect is also improved.

FIGS. 2 to 4 are cross-sectional views illustrating an ion generating device according to another embodiment of the present invention, respectively. 2 to 4, members common to those in Fig. 1 are assigned the same numerals.

In the ion generating apparatus shown in Fig. 1, the conduit 24 is directly mounted on the nozzle 23. Fig. Conversely, in the ion generating device 10b shown in Fig. 2, the conduit 24 is mounted on the nozzle 23 by the fitting 30. Fig. The other structures are the same as the ion generating device 10a shown in Fig.

3, the nozzle 23 is provided with a nozzle main body portion 23a and a nozzle main body portion 23a provided in the conduit 24, and the discharge main body 23a is attached to the discharge main body 23a. And a nozzle holder portion (23b) mounted on the nozzle body (11). A plurality of air inlets 27 are formed in the nozzle holder portion 23b to introduce air from the outside into the air ions generated through the ion generation flow path 15 as indicated by the arrow B in FIG. The nozzle holder portion 23b is also formed with an arc surface 28 for guiding the air introduced from the air inlets 27 to the nozzle main body portion 23a. An ejector 29 for introducing outside air from the air inlets 27 by the arc surface 28 and for introducing air ions passing through the ion generating flow path 15 and flowing inside the nozzle holder portion 23b, .

In addition, the nozzle holder portion 23b of the nozzle 23 is provided with auxiliary air for introducing air to mixed air ions to which air flows from the air inlets 27 are added to the air ions as shown by arrow D An inlet 32 is formed. The auxiliary air inlet 32 communicates with the base end surface of the nozzle main body portion 23a of the nozzle 23. [ A contraction portion 25 having an inner diameter substantially equal to the inner diameter d of the ion generation flow path 15 is formed in the nozzle main body portion 23a and a tapered portion 25b having an inner diameter gradually increasing toward the inner side surface of the conduit 24 A surface 26 is formed on the tip side from the constriction 25. The auxiliary ejector 34 is formed by the constricted portion 25, the tapered surface 26 and the arc surface 28. The auxiliary ejector 34 is formed from the auxiliary air inlet 32 by using air ions flowing inside the nozzle main body portion 23a Introduces outside air.

By this arrangement, outside air is passed through the ion generating flow path 15 and the air ions flowing in the inside of the nozzle 23 in one step by the ejector 29 and in two steps by the auxiliary ejector 34 . Therefore, even if the amount of compressed air supplied to the supply port 21 is reduced, a large amount of air ions can be sprayed on the members requiring static elimination.

4 is a cross-sectional view of an ion generating device 10d according to another embodiment of the present invention. In the above-described ion generating devices 10a to 10c, the rod-like discharge electrodes 16 are disposed so as to coaxially extend in the radial direction of the ion generation flow path 15. [ In contrast, in the ion generating device 10d shown in Fig. 4, the discharge electrodes 16 are arranged radially in a direction transverse to the ion generation flow path 15. In the discharge unit 11 of the ion generating device 10d, the discharge electrode 16 forms an ion generating flow path 15 and is attached to a circular isolating member 14 made of a laser material, The tip portion of the discharge electrode 16 is located at the center line of the ion generation flow path 15. The opposite electrode is attached to the isolation member 14 opposite to the discharge electrode 16. [

Similar to the ion generating device 10a of Fig. 1, the tip portion of the discharge unit 11 made of an isolating material such as a raylee serves as a nozzle 23, and a conduit for guiding air ions to a member requiring static elimination (24) is mounted on the tip portion of the nozzle (23). The contraction portion 25 and the inner diameter of the nozzle 23 gradually increase toward the inner side surface of the conduit 24 and the tapered surface 26 located at the tip side of the contraction portion 25 is formed, A plurality of air inlets 27 for introducing air from the outside are formed as shown by the arrow B with respect to the air ions generated through the plurality of air inlets 15, An arc surface 28 is formed in the nozzle 23 for guiding the air introduced from the air inlets 27 to the contracting portion 25, similarly to the ion generating device 10a in Fig. The ejector 29 for introducing the outside air from the air inlets 27 and for introducing the air ions flowing through the ion generating flow path 15 and flowing inside the nozzle 23 is connected to the contraction portion 25, The surface 26 and the arc surface 28. As shown in Fig.

Also, in the ion generating devices 10c and 10d of Figs. 3 and 4, even if the amount of compressed air supplied to the supply port 21 is reduced, neutralization of negative ions and positive ions is prevented from occurring, The amount of air ions sprayed on the member requiring static elimination at the tip of the electrode 24 is not so reduced and the static electricity charged in the member requiring the static elimination can be removed in a short time. Further, since the air inlets 27 are formed on the downstream side of the discharge electrode 16, the outside air from the air inlets 27 is introduced into the air ions ionized by the discharge electrode 16. Therefore, the ion balance of the air ions coming out of the conduit 24 is improved, and the electrostatic elimination effect can also be improved.

5 and 6 show ion generating devices as comparative examples, respectively. In the ion generating device 10e of Fig. 5, the arrangement of the discharge electrodes 16 is similar to the ion generating devices 10a-10c shown in Figs. 1 to 3, respectively. An air supply unit 12 in which an air-supply port 22 communicating with the supply port 21 is formed is provided as a cylindrical isolating member 14 in which an ion-generating flow path 15 is formed and a discharge electrode 16 protrude into the ion generation flow path 15 and are attached to the air supply unit 12. The opposite electrode 13 on which the conduit 24 is mounted is mounted on the isolating member 14 and the opposite electrode 13 acts as a nozzle. As described above, the ion generator 10e of the comparative example is not provided with the ejector 29. [

On the other hand, the ion generating device 10f shown in Fig. 6 is similar to the ion generating device 10d shown in Fig. 4 in the arrangement of the discharge electrodes 16. Fig. The discharge electrode 16 and the counter electrode 13 are provided in the nozzle 23 connected to the air supply unit 12 through the spacer 35 and the air supply unit 12 is provided with the air A supply port 22 is formed, and a discharge unit is formed by the nozzle 23. [ An arc surface 28 and a tapered surface 26 for guiding the air introduced from the air inlets 27 are formed on the upstream side of the ion generation flow path 15 formed on the tip portion side of the nozzle 23. An ejector 29 for introducing outside air from the air inlets 31 to the air supplied from the air-supply port 22 and the suction port 31 to the nozzle 23 is provided between the arc surface 28 and the tapered surface 26). Thus, in the ion generating device 10f of the comparative example, air is ionized by the discharge electrode 16 and the counter electrode 13 on the downstream side of the ejector 29. [

FIG. 7A is a characteristic line diagram showing the static elimination effect of the ion generating device 10e of FIG. 5 as a comparison example with the ion generating device 10a of FIG. FIG. 7B is a characteristic line diagram showing the static elimination effect of the ion generating device 10e as a comparative example to the ion generating device 10c of FIG. 7A and 7B, the vertical axis represents the static elimination time, and the horizontal axis represents the flow rate of the air supplied from the supply port 21.

In measuring each characteristic line, a 500 mm long conduit 24 was used and the static elimination time was measured by spacing a charged plate monitor 50 mm from the tip of the conduit 24. Therefore, as shown in FIG. 7A, since the ion generators 10a-10c of FIGS. 1 and 3 of the present invention are provided with the ejectors 29, their electrostatic elimination times may be shorter than those of the comparative examples . Particularly, when the flow rate of the compressed air supplied from the supply port 21 is reduced, the effect of reducing the static elimination time by the ion generating devices of the present invention becomes more remarkable as compared with the comparative examples. 7B, when the auxiliary air is supplied from the auxiliary air inlet 32 similarly to the arrangement of the ion generating device 10c, even when the amount of the compressed air supplied from the supply port 21 is large , The effect of reducing the static elimination time becomes more remarkable. The ion generating device 10b shown in FIG. 2 also has an effect similar to that of the ion generating device 10a.

Meanwhile, FIG. 8A is a data showing a confirmation experiment result of measuring the disturbance of the ion balance by forcibly injecting the fine particles into the ion generation flow path 15 with respect to the ion generating device 10d according to the present invention of FIG. 4 . Fig. 8B is a data showing the result of confirmation experiment with respect to the ion generating device 10f of the comparative example shown in Fig.

Each experiment was carried out using an ion generating device in which a 100 mm long conduit 24 was mounted on the nozzle 23 and 0.1 MPa of compressed air was supplied from the supply port 21 to the ion production flow path 15 . In consideration of the ion generating device used in a place where the surrounding atmosphere is inappropriate, fine particles are forcedly injected from the air inlets 27. Therefore, in the ion generating device 10f of the comparative example, disturbance of the ion balance occurred within tens of seconds after introduction of the foreign substance. However, in the ion generating device 10d according to the present invention, disturbance of ion balance did not occur. Therefore, even when the ion generating device of the present invention is used in an inappropriate air atmosphere, the ion balance can be improved by introducing outside air from the air inlets 27 on the downstream side of the discharge electrode 16. [

Fig. 9 is a characteristic line diagram showing the ion balance effect of the ion generating device 10d of the present invention illustrated in Fig. 4 and the ion generating device 10f of Fig. 6 as a comparative example. The vertical axis of FIG. 9 represents the ion balance, and the horizontal axis represents the air supply pressure. FIG. 9A shows the measurement result obtained using the conduit 24 having a length of 100 mm, and FIG. 9B shows the measurement result obtained using the conduit 24 having a length of 500 mm. the results are as follow. That is, in the ion generating device 10d of the present invention shown in Fig. 4, even when the air supply pressure changes, there is no significant change in the ion balance. As a comparative example, in the ion generating device 10f, The ion balance also changed greatly. As shown in the comparative example, it is considered that a large change in the ion balance is caused by air disturbance caused by the structure of the ejector 29 because the air is ionized after introduction of the outside air to the downstream side of the ejector.

Therefore, when external air is introduced by the ejector 29 using the flow of the air ions obtained after the ionization of air as in the present invention, air ions having excellent ion balance can be sprayed on the member requiring the removal of static electricity. The static elimination effect is also improved.

The above-described conduit 24 is not attached to the nozzle 23 in each of the ion generating apparatus 10g shown in Fig. 10 and the ion generating apparatus 10h shown in Fig. The ion generating device 10g shown in FIG. 10 has the same basic structure as the ion generating device 10a shown in FIG. 1, and the ion generating device 10h shown in FIG. And has the same basic structure as the device 10c. In these ion generating devices 10g and 10h, air ions are blown out from the air discharge port 19 of the nozzle 23 to a member requiring static elimination.

The present invention is not limited to the above-described embodiments, and various changes are possible within the scope of the present invention. For example, in each of the discharge units 11 of Figs. 1 to 3, the discharge electrode 16 and the opposite electrode 13 are opposed to each other by inserting the isolating member 14 therebetween, Can be directly opposed.

11: Discharge unit
12: Air Supply Unknown
13: counter electrode
14: Insulation member
15: ion production flow path
16: discharge electrode
17: Power supply unit
20: Compression-air pressure source
21: Supply port
22: Air supply ports
23: conduit holder
24: the conduit
25:
26: Taper face
27: air inlets
28: arc face
29: Ejector
30: Fitting
31: Suction ports
32: auxiliary air inlets
34: Secondary ejector

Claims (7)

1. An ion generating device having a discharge electrode and an opposite electrode provided opposite to the discharge electrode and generating an air ion by generating a corona discharge by applying a high alternating current across the discharge electrode and the opposite electrode, The
A discharge unit including a discharge electrode, an opposite electrode, and an ion generation flow path formed inside the discharge unit; And
An air supply unit disposed at the base end of the discharge unit and having an air-supply port communicating with the ion generation flow path and supplying compressed air to the ion generation flow path; It includes
The tip of the discharge unit is provided with an air inlet for introducing outside air from the outside,
And an ejector for introducing outside air from the air inlet to the air ions passing through the ion generation flow path is provided on the downstream side of the air inlet located at the tip portion of the discharge unit. The ion generating device according to claim 1, wherein the discharge electrode is coaxially arranged at the center of the ion generating flow path. The ion generating device according to claim 1, wherein the discharge electrode is disposed in a direction transverse to the ion generating flow path. The air conditioner according to any one of claims 1 to 3, wherein a discharge port is provided at the base end of the discharge unit, and the suction port sucks the outside air by the air blown out from the air- And supplying external air into the ion generation flow path. 4. A method according to any one of claims 1 to 3, wherein the tip portion of the discharge unit has an auxiliary air inlet, wherein the auxiliary air inlet is configured such that air flow from the air inlet is added to the air ions, For supplying external air to the ion generating device. The ion generating device according to any one of claims 1 to 3, wherein the inner diameter of the air discharge port of the discharge unit is larger than the inner diameter of the ion generation flow path. 4. The ion generating device according to any one of claims 1 to 3, wherein the conduit for guiding air ions emitted from the discharge unit to a member requiring static elimination is mounted on a tip portion of the discharge unit.

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