KR102119272B1 - Discharge apparatus having electrode for shielding electromagnetic wave - Google Patents

Abstract

Disclosed is a static electricity eliminator including: a static electricity eliminator body having an air passage through which high pressure air is supplied; a plurality of discharge structures installed at a lower end of the static electricity eliminator body to supply high-pressure air, which has passed through the air passage, and generating positive/negative ions through discharge by applied high voltage; and an electrode for shielding electromagnetic wave having a plurality of openings formed to allow the positive/negative ions and high pressure air to pass therethrough, and installed to cover at least a portion of the plurality of discharge structures.

Description

A static electricity elimination device equipped with an electrode for blocking electromagnetic waves {DISCHARGE APPARATUS HAVING ELECTRODE FOR SHIELDING ELECTROMAGNETIC WAVE}

The present invention relates to a static electricity elimination device that removes static electricity from a large electricity by using ion generation, and more particularly, to provide an electrode for blocking electromagnetic waves that can improve the static electricity removal performance for the large electricity by providing an electrode capable of blocking electromagnetic waves. It relates to a static electricity elimination device provided.

The static electricity elimination device is a device for removing static electricity using corona discharge. In general, a high voltage is applied to a discharge structure including a discharge pin to generate corona discharge between adjacent counter electrodes, thereby inducing ion generation. When the applied high voltage is a positive (+) voltage, positive (+) ions are generated, and when the applied high voltage is a negative (-) voltage, negative (-) ions are generated.

The ions generated in this way are carried in a high-pressure air supplied to the air holes of the discharge structure through a separate blowing means and are discharged in the direction of the electrification to defuse the electrification. For example, when the whole body is positively charged, it can be neutralized by pushing the positive ions and bonding with the negative ions.

Typically, there are two methods for generating the cations and anions. First, a positive (+) voltage is applied to one of the two adjacent discharge pins and a negative (-) voltage is applied to the other. It is a method of applying, and the second is a method of sequentially generating ions by applying a positive (+) voltage and a negative (-) voltage to one discharge pin as pulses.

As described above, the ions generated in the static elimination device are lowered in concentration as they are carried on high pressure air, and thus, it is common that the static electricity elimination performance decreases as the whole body is located at a long distance.

However, when the distance between the static elimination device and the whole body becomes an ultra-short distance, for example, about 10 mm, a phenomenon in which the static electricity removal performance of the whole body is rather deteriorated occurs, but a clear theoretical basis for this is not yet presented.

Accordingly, there is a need for a technique capable of improving the static electricity elimination performance for a large current even when the distance between the antistatic device and the large current is extremely narrow.

The present invention has been devised in view of the above-described problems, and the distance from the electrification is extremely short distance by interposing an electrode for blocking electromagnetic waves between the electrification and the static elimination device by focusing on the influence of electromagnetic waves in addition to ions generated by the static electricity elimination. An object of the present invention is to provide a static electricity elimination device capable of improving static electricity elimination performance.

Another object of the present invention is to provide a static electricity elimination device that can employ an electromagnetic wave blocking electrode in various structures and methods.

In order to achieve the above object, a static electricity elimination apparatus according to an embodiment of the present invention, the static eliminator body is formed with an air passage through which high pressure air is supplied; A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And a plurality of openings to allow the positive/negative ions and high pressure air to pass therethrough, and to include at least a portion of the plurality of discharge structures.

The static elimination apparatus of the present invention having the above-described configuration is provided with an electrode capable of blocking electromagnetic waves between the static electricity elimination apparatus and the static electricity elimination performance even when the distance between the static electricity elimination apparatus and the whole electricity is very short. It provides an effect.

In addition, in the static electricity elimination device according to the present invention, the electromagnetic wave blocking electrode is configured to be easily detachable as necessary, so that cleaning and maintenance of the discharge structure can be conveniently performed.

The improved effects and advantages of the present invention will be more clearly understood through the following detailed description.

The present invention is specifically described by the following drawings, but these drawings represent embodiments of the present invention and should not be construed as limiting the technical idea of the present invention only to the drawings.
1A is a partially exploded perspective view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to an embodiment of the present invention.
1B is a perspective view schematically showing an external appearance of a static electricity elimination device having an electromagnetic wave blocking electrode shown in FIG. 1A.
2A and 2B are a partially cut-away perspective view and a side cross-sectional view showing a schematic configuration of a static electricity elimination apparatus having an electrode for blocking electromagnetic waves according to an embodiment of the present invention.
3 is a perspective view schematically showing the configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
4A is a partially exploded perspective view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
4B is a perspective view schematically showing the appearance of a static electricity elimination device having an electrode for blocking electromagnetic waves illustrated in FIG. 4A.
5 is a partially exploded perspective view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
6 is a bottom view showing a schematic configuration of a static electricity elimination apparatus having an electrode for blocking electromagnetic waves according to another embodiment of the present invention.
7 is a perspective view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
8 is a side view showing a schematic configuration of a static electricity elimination device having an electromagnetic shielding electrode according to another embodiment of the present invention.
9A is a perspective view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
9B is a diagram schematically showing a cross-section of an electrode for blocking electromagnetic waves provided in the static elimination device shown in FIG. 9A.
10A and 10B are a front view and a bottom view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode according to another embodiment of the present invention.
11A is a graph showing an electromagnetic wave waveform measured during a static electricity elimination operation by a static electricity elimination device without an electromagnetic wave blocking electrode.
11B is a graph showing an electromagnetic wave waveform measured during a static electricity elimination operation by a static electricity elimination apparatus having an electromagnetic wave blocking electrode.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of an artificial reef with a curved wall according to a preferred embodiment of the present invention. Prior to this, since the configuration shown in the detailed description and drawings of this specification is only an embodiment of the present invention, it should be understood that there may be various equivalents and modifications that can replace them at the time of application. . In addition, in the drawings attached to the present specification, the same reference numerals denote the same components.

1A is a partially exploded perspective view showing a schematic configuration of an antistatic device having an electromagnetic shielding electrode according to an embodiment of the present invention, and FIG. 1B is an external view of an antistatic device having an electromagnetic shielding electrode shown in FIG. 1A It is a perspective view schematically showing.

Referring to the drawings, a static electricity elimination device according to an embodiment of the present invention includes a static electricity elimination unit 100 that generates ions by corona discharge, and an electromagnetic wave blocking electrode 200 provided in the static electricity elimination unit 100. It is composed.

The antistatic device has a configuration capable of generating positive and negative ions by high-voltage discharge and then discharging them into a large body (not shown) using high-pressure air, and specific examples thereof are illustrated in FIGS. 2A and 2B. 2A and 2B are a partially cut-away perspective view and a side cross-sectional view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode 200 according to an embodiment of the present invention.

Referring to the drawings, the static electricity elimination apparatus according to an embodiment of the present invention is configured to be formed in the form of an extruded bar, for example, so that an air passage 12 is formed in the upper space 11 and the lower portion thereof. The static electricity elimination body 10 may include a plurality of discharge structures 20 installed to be spaced apart at predetermined intervals in the longitudinal direction on the lower surface of the static electricity elimination body 10.

In the upper space 11, a control unit 13 and an operation panel (not shown) and a connector (not shown) for controlling and manipulating the static electricity elimination device may be stored, and an upper surface cover 14 is provided in the upper surface opening part. Can be installed and closed. Connection brackets 30 are coupled to both ends of the top cover 14 by fastening means such as bolts, and the connection brackets 30 are fixed brackets for fixing the antistatic device to a separate structure (not shown) ( 31). Preferably, the connecting bracket 30 is formed with an arc-shaped slot 33, through the arc-shaped slot to the fixing screw 34 for mutually fixing the connection of the connecting bracket 30 and the fixing bracket 31 By this, it is possible to arbitrarily adjust the relative installation angle of the static electricity elimination device.

The air passage 12 is formed to extend through the longitudinal direction of the static eliminator body 10, and is a passage through which high-pressure air is blown from the outside, and the high-pressure air thus supplied is a discharge structure as described below. It can be supplied to (20).

A side cover 40 is installed at both ends of the static eliminator body 10, and a separate air supply pipe (not shown) is connected to a coupling hole formed in the side cover 40 so as to communicate with the air passage 12. The air inlet terminal 41 may be installed. In addition, between the static eliminator body 10 and the side cover 40 so as not to leak high-pressure air flowing into the static eliminator body 10 through the air inlet terminal 41 and the air passage 12, a gasket, etc. A sealing member (not shown) may be further provided.

A plurality of openings may be formed at a predetermined interval in the longitudinal direction so as to communicate with the air passage 12 on the lower surface of the static eliminator body 10, and a discharge structure 20 may be installed in each opening. have. The discharge structure 20 may include a support member 21 for fixing and supporting the discharge pin, and an annular bracket member 22 for detachably supporting the support member 21.

The support member 21 is provided with an insertion hole 24 having an inner diameter such that a discharge pin 23 can be inserted and fixed, and a lower portion where the tip of the discharge pin 23 is located is widely opened to discharge pin The ions generated from 23 may be configured to be smoothly released together with high pressure air. An air flow groove 25 may be further formed on the inner surface of the insertion hole 24 into which the discharge pin 23 is inserted and coupled so that the high pressure air supplied from the air passage 12 flows downward.

At least one vent 26 communicating with the air passage 12 may be formed on a side surface of the annular bracket member 22, and air introduced through the vent 26 may be the air flow groove 25. It can be discharged through the support member 21 through.

A conductive connecting screw 28 in electrical contact with a conductive plate 27 to which voltage is supplied is installed on an upper portion of the annular bracket member 22, and a lower portion of the conductive connecting screw 28 is provided with a discharge pin 23. It may be connected to the conductive metal tube 29 to be combined. Therefore, the voltage supplied to the conductive connection screw 28 through the conductive plate 27 may be applied to the discharge pin 23 through the metal tube 29.

The static electricity elimination apparatus according to the present invention, as shown in FIGS. 1A and 1B, may be provided with an electrode 200 for blocking electromagnetic waves interposed between the whole and blocking electromagnetic waves. Preferably, the electromagnetic shielding electrode 200 may be installed to be interposed between the discharge structure 20 and the whole, specifically, a plurality of discharge structures 20 provided on the lower surface of the static eliminator body 10 It can be installed to cover at least a portion of.

The electromagnetic shielding electrode 200 may be made of various metals, such as iron, aluminum, copper, or alloys thereof, to obtain an electromagnetic shielding effect, and is not limited to a specific metal. As another alternative, the electromagnetic shielding electrode 200 may be manufactured by plating or coating a metal material on a non-metal material.

At the same time, the electromagnetic wave blocking electrode 200 according to the present invention allows ions generated from the discharge structure 20 to pass through with high pressure air and be smoothly released toward the whole body (that is, does not block or block the flow) So that) a plurality of openings are formed, and for this purpose, preferably, the electromagnetic wave blocking electrode 200 may be configured in a mesh (wire mesh) form, but is not necessarily limited thereto. For example, the electromagnetic shielding electrode 200 may be made of a metal plate (not shown) in which a plurality of through holes are formed, or may be manufactured in a grill form (not shown) in which metal wires are arranged in one direction (horizontal or vertical). As it may be, it should be understood that it can be manufactured in various forms that can be inferred or modified by a person having ordinary skill in the art.

The electromagnetic wave blocking electrode 200 illustrated in FIGS. 1A and 1B includes a side portion 200S covering at least a portion of both sides of the static eliminator body 10 and a plurality of discharges installed on the lower surface of the static eliminator body 10. It may be composed of a mesh-shaped electrode bent to have a lower portion (200B) that covers at least a portion of the structure (20).

At least a portion of the upper end of the side portion 200S of the electromagnetic wave blocking electrode 200 is bent toward the inside to form a continuous or non-continuous bending end portion 201, and the bending end portion 201 is the electrostatic body ( It can be attached to the static electricity elimination body 10 by being coupled to the sliding groove (G) is formed extending in the longitudinal direction on the side. According to this embodiment, the electromagnetic wave blocking electrode 200 is coupled to the sliding groove G formed in the static eliminator body 10 as necessary (for example, for cleaning and maintaining the discharge structure 20) It can be attached and detached freely when necessary.

As another alternative, at least a portion of the upper end of the side surface 200S of the electromagnetic wave blocking electrode 200 is bent toward the inside to form a continuous or discontinuous bending end or hook (not shown), and this bending end or The hook may be attached to the static eliminator body 10 by elastically fitting or forcibly fitting to a coupling groove (not shown) formed on the side surface of the static eliminator body 10. Preferably, the sliding groove (G) may function as the coupling groove.

3 is a perspective view schematically showing a configuration of a static electricity elimination device having an electromagnetic wave blocking electrode 200 according to another embodiment of the present invention.

The electromagnetic wave blocking electrode 210 according to the present embodiment includes a side portion 210S covering at least a portion of both sides of the static eliminator body 10 and a plurality of discharge structures 20 installed on the lower surface of the static eliminator body 10. The configuration is the same as the electromagnetic wave blocking electrode 200 shown in FIGS. 1A and 1B in that it is formed of a mesh-shaped electrode bent to have at least a lower portion 210B covering at least a part. Therefore, also in the electromagnetic wave blocking electrode 210 according to the present embodiment, at least a portion of the upper end of the side portion 210S is bent toward the inside to form a continuous or discontinuous bent end portion 201. However, according to the present embodiment, the sliding groove G for attaching the electromagnetic wave blocking electrode 210 is formed on the top surface of the static eliminator body 10, or the top surface of the static eliminator body 10 The middle edge may serve as the sliding groove (G).

In the present embodiment, in order to install the electrode 210 for blocking electromagnetic waves, it may not be necessary to form a separate sliding groove G on the side of the static eliminator body 10, and also the electrode 210 for blocking electromagnetic waves The electromagnetic panel blocking effect can be further increased by covering the entire side surface of the static eliminator body 10. Further, according to this embodiment, the electromagnetic wave blocking electrode 210 is freely attached or detached to the static eliminator body 10 as necessary (for example, when necessary for cleaning and maintenance of the discharge structure 20). can do.

As another alternative, at least a portion of the upper end of the side portion 210S of the electromagnetic wave blocking electrode 210 is bent toward the inner side to form a continuous or discontinuous bending end portion 201, and the bending end portion 201 is It may also be attached to the static elimination body 10 by being coupled to the elastic fit or interference fit on both sides of the top surface of the static elimination body 10.

4A is a partially exploded perspective view showing a schematic configuration of an antistatic device having an electromagnetic shielding electrode 220 according to another embodiment of the present invention, and FIG. 4B is an electromagnetic shielding electrode 220 shown in FIG. 4A It is a perspective view schematically showing the appearance of a static electricity elimination apparatus having a.

The electromagnetic wave blocking electrode 220 according to the present embodiment may include two or more sub-electrodes 221 and 222 covering at least a portion of the static eliminator body 10. The electromagnetic wave blocking electrode 220 shown in this embodiment may be configured of, for example, a first sub-electrode 221 and a second sub-electrode 222. Each sub-electrode 221 or 222 includes a side portion 220S covering at least a portion of both sides of the static eliminator body 10 and at least a portion of a plurality of discharge structures 20 provided on a lower surface of the static eliminator body 10. It may be formed of a mesh-shaped electrode bent to have a lower portion (220B) covering the.

At least a portion of the upper end of the side portion 220S of each sub-electrode 221 or 222 is bent toward the inner side to form a continuous or discontinuous bending end portion 201, and the bending end portion 201 is the static eliminator body By being coupled to the sliding groove (G) formed to extend in the longitudinal direction on the side of (10) it can be attached to the static eliminator body (10). According to this embodiment, each sub-electrodes 221 and 222 are coupled to the sliding groove G formed in the static eliminator body 10 as necessary (for example, cleaning and maintenance of the discharge structure 20). Can be attached and detached freely.

Furthermore, in the electromagnetic shielding electrode 220 according to the present embodiment, each of the sub-electrodes 221 and 222 is individually detachable, and when attached to the static eliminator body 10, shown in FIG. 4B As shown, the opening OP is secured between the sub-electrodes 221 and 222 (in the embodiment of FIG. 4B) or on one side (when all of the sub-electrodes 221 and 222 are collected by sliding to one side) Therefore, the discharge structure 20 can be cleaned or maintained without completely removing the electromagnetic wave blocking electrode 220 from the static eliminator body 10.

As another alternative, at least a portion of the upper ends of the side portions 220S of the sub-electrodes 221 and 222 are bent toward the inner side to form a continuous or discontinuous bending end portion 201, and the bending end portion 201 is It may be attached to the static electricity elimination body 10 by an elastic fitting or interference fit to the coupling groove (not shown) formed on the side surface of the static electricity elimination body 10.

5 is a partially exploded perspective view showing a schematic configuration of an antistatic device having an electromagnetic wave blocking electrode 230 according to another embodiment of the present invention.

The electromagnetic wave blocking electrode 230 according to this embodiment includes a side portion 230S covering at least a portion of both sides of the static eliminator body 10 and a plurality of discharge structures 20 installed on the bottom surface of the static eliminator body 10. It is composed of a mesh-shaped electrode bent to have a lower portion 230B that covers at least a portion. At least a portion of the upper end of the side portion 230S of the electromagnetic wave blocking electrode 230 is bent toward the inside to form a continuous or non-continuous bending end portion 201, and the bending end portion 201 is the electrostatic body ( It can be attached to the static electricity elimination body 10 by being coupled to the sliding groove (G) is formed extending in the longitudinal direction on the side. According to this embodiment, the electromagnetic wave blocking electrode 230 is coupled to the sliding groove G formed in the static eliminator body 10 as necessary (for example, for cleaning and maintaining the discharge structure 20) It can be attached and detached freely when necessary.

In addition, according to the present embodiment, the length L1 of the electromagnetic wave blocking electrode 230 is set to be smaller than the length L2 of a plurality of discharge structure 20 rows installed at the bottom of the static eliminator body 10. . Therefore, when the electromagnetic wave blocking electrode 230 is moved to one side, an opening can be secured to the opposite side, so that the discharge structure 20 can be removed without completely removing the electromagnetic wave blocking electrode 200 from the static eliminator body 10. It can be cleaned or maintained.

As another alternative, at least a portion of the upper end of the side portion 230S of the electromagnetic wave blocking electrode 230 is bent toward the inside to form a bent end portion 201, which is the bent end body 201. The coupling groove (not shown) formed on the side surface of 10) may be attached to the static eliminator body 10 by being fitted with an elastic fit or an interference fit.

In the electrodes for electromagnetic shielding described above, a separate cleaning opening hole may be further formed for cleaning or maintenance of the discharge structure 20, and an example of such a configuration is illustrated in FIG. 6. That is, as illustrated in FIG. 6, in the electrode 240 for blocking electromagnetic waves, at least one of the lower portions 240B covering at least a portion of the plurality of discharge structures 20 installed on the lower surface of the static eliminator body 10 is provided. The opening hole H for cleaning as described above is formed, and through this, cleaning or maintenance of the discharge structure 20 is possible. In particular, as shown in (a) and (b) of FIG. 6, when the electromagnetic wave blocking electrode 240 has a structure that is slidable in the longitudinal direction of the static eliminator body 10, the electromagnetic wave blocking electrode 240 ) By sliding properly, the opening hole for cleaning (H) is adjustable to be located at a desired point.

7 is a perspective view showing a schematic configuration of an antistatic device having an electromagnetic wave blocking electrode 250 according to another embodiment of the present invention.

The electromagnetic wave blocking electrode 250 according to the present embodiment includes a side portion 250S covering at least a portion of both side surfaces of the static eliminator body 10 and a plurality of discharge structures 20 installed on the lower surface of the static eliminator body 10. It is composed of a mesh-shaped electrode bent to have a lower portion (250B) that covers at least a portion of the.

The electromagnetic wave blocking electrode 250 may be fixed to the static eliminator body 10 by a fastening member F such as a bolt. Specifically, a plurality of bolt fastening holes (not shown) are formed on the side surface of the static eliminator body 10, and a through hole 251 through which the bolt penetrates may be formed in the electromagnetic wave blocking electrode 250.

Therefore, as shown, by fastening a fastening member (F) such as a bolt to the bolt fastening hole formed on the side of the static elimination body 10 through the through hole 251, the electromagnetic wave blocking electrode 250 is a static elimination body It can be attached to (10). Although the drawing shows an example in which the electromagnetic wave blocking electrode 250 is attached by fastening three fastening members F on one side, the number and coupling positions of the fastening members F are not limited by this embodiment. Does not.

8 is a side view showing a schematic configuration of an antistatic device having an electromagnetic wave blocking electrode 260 according to another embodiment of the present invention.

The electromagnetic wave blocking electrode 260 according to the present embodiment includes a side portion 260S that covers at least a part of one side of the static eliminator body 10, and a plurality of discharge structures 20 provided on the bottom surface of the static eliminator body 10. ) Is formed of a mesh-shaped electrode bent to have a lower end portion 260B covering at least a portion. Unlike the above-described embodiments, the electromagnetic wave blocking electrode 260 according to the present embodiment is configured such that the lower end 260B extends from the lower end of the side part 260S, and the other side of the static eliminator body 10. There is no side portion to cover it.

In addition, the side portion 260S of the electromagnetic wave blocking electrode 260 is coupled to the static eliminator body 10, more preferably, the upper cover 14 to be rotatable within a predetermined range by a hinge member HG. Can be. Specifically, one end of the hinge member (HG) may be fixed by a fastening means such as a bolt to the top cover 14 provided on the top of the static eliminator body 10, the other end of the hinge member (HG) is the electromagnetic wave On the upper side of the side portion 260S of the blocking electrode 260, a fastening member, soldering, or welding may be combined by other methods. Therefore, the electromagnetic wave blocking electrode 260 of this embodiment is rotatable in the direction of arrows A and B shown with respect to the static eliminator body 10.

For example, during the static electricity elimination operation to remove static electricity from the whole body, the electromagnetic wave blocking electrode 260 is rotated in the direction of the arrow (A), and the lower end portion 260B is provided on the lower surface of the static electricity elimination body 10. To cover at least a portion of the plurality of discharge structures 20, on the contrary, during cleaning/maintenance, the electromagnetic wave blocking electrode 260 is rotated in the opposite direction B to expose the plurality of discharge structures 20. It can be done. Therefore, if necessary, for example, when necessary for cleaning and maintenance of the discharge structure 20, it is very easy to attach and detach the electromagnetic wave blocking electrode 260.

9A is a perspective view showing a schematic configuration of an antistatic device having an electromagnetic wave blocking electrode 270 according to another embodiment of the present invention, and FIG. 9B is an electromagnetic wave blocking electrode provided in the antistatic device shown in FIG. 9A It is a figure showing the cross section of 270 schematically.

9A and 9B, the electromagnetic wave blocking electrode 270 includes a side portion 270S covering at least a portion of both sides of the static eliminator body 10 and a plurality of discharges installed on the lower surface of the static eliminator body 10. It is composed of a mesh-shaped electrode bent to have a lower portion (270B) covering at least a portion of the structure (20).

According to the present embodiment, the side portion 270S of the electromagnetic wave blocking electrode 270 may be configured in a shape in which the distance between them decreases from the bottom to the top as shown in the cross-sectional view of FIG. 9B. At this time, the distance between the upper ends of the side portions 270S is set to be smaller than the width of the static eliminator body 10.

The electromagnetic shielding electrode 270 configured as described above may be attached by being elastically fitted to the lower end of the static eliminator body 10. That is, since the electromagnetic wave blocking electrode 270 made of metal retains some elasticity, while extending the side portions 270S of the electromagnetic wave blocking electrode 270 to both sides, the lower end of the static eliminator body 10 therebetween. When is inserted, since the gap between the top of the side portion 270S is narrower than the width of the static eliminator body 10, the electromagnetic wave blocking electrode 270 is attached by elastically clamping both sides of the static eliminator body 10 Can be.

Preferably, at least a portion of the upper end of the side portion 270S of the electromagnetic wave blocking electrode 270 is bent inward to form a continuous or discontinuous bending end portion 201, and the bending end portion 201 is removed from the static electricity elimination body. The electromagnetic wave blocking electrode 270 may be attached to the coupling groove (not shown) formed on the side surface of (10) by elastic fitting or forcing fitting.

As another alternative, the upper end of the side portion 270S is bent outward to facilitate the insertion of the static eliminator body 10 between the side portions 270S of the electromagnetic wave blocking electrode 270, and thus an insertion guide portion (not shown) It may form.

On the other hand, when the electromagnetic shielding electrode 270 is removed for cleaning or maintenance of the discharge structure 20, the electrode can be pulled downward to be easily separated from the static eliminator body 10.

10A and 10B are a front view and a bottom view showing a schematic configuration of a static electricity elimination device having an electromagnetic wave blocking electrode 280 according to another embodiment of the present invention.

According to this embodiment, the plurality of discharge structures 20 provided at the bottom of the static eliminator body 10 may be provided with electrodes 280 for blocking electromagnetic waves, respectively. That is, the electromagnetic wave blocking electrode 280 is formed to a size sufficient to cover each discharge structure 20, and is independently attached to the lower surface of the discharge structure 20 or the static eliminator body 10. Can be.

In this embodiment, an elliptical electromagnetic wave blocking electrode 280 corresponding to its shape is shown to accommodate the discharge structure 20, but the shape and size of the electromagnetic wave blocking electrode 280 are not limited by this embodiment. No, the shape and size may be variously set as long as the discharge structure 20 can be independently covered.

In addition, the structure for attaching the electromagnetic wave blocking electrode 280 to the lower surface of the discharge structure 20 or the static eliminator body 10 may be designed in various ways, for example, to form a hook on one side and on the other side. Electrodes for blocking electromagnetic waves 280 may be attached to each other by providing a locking portion. In addition, by using a separate fastening means, the electromagnetic wave blocking electrode 280 may be attached to the lower end of the discharge structure 20 or the static eliminator body 10.

So far, the electromagnetic shielding electrode of the above-described embodiments has been described as being limited to a mesh-type electrode, but this is only a simple example presented in the convenience for explaining the present invention, and has the same concept of configuration and coupling structure with electromagnetic shielding of different types. It should be understood that the same can be applied to an electrode (for example, an electromagnetic shielding electrode formed by bending a metal plate having a plurality of through holes or a grill-type electromagnetic shielding electrode formed by arranging a plurality of metal wires in one direction). .

Furthermore, it should be understood that not only the above-described embodiments, but also configurations made by combining all or some of these configurations with each other fall within the scope of the present invention. For example, although not shown and described, the configuration illustrated in FIGS. 4A and 4B and the configuration illustrated in FIG. 5 block electromagnetic waves illustrated in FIGS. 1A and 1B, 3, 5, and 7 to 9B. The same can be applied to the dragon electrodes.

Then, the operation of the static electricity elimination apparatus according to the embodiment of the present invention having the above configuration will be described.

The static electricity elimination device according to the present invention is brought into close contact with an object to remove static electricity, and an antistatic operation is performed. At this time, a high voltage preset through the control unit and the operation panel is supplied to the conductive plate 27 provided on the top of the annular bracket member 22, and the supplied high voltage is a conductive connection screw contacting the conductive plate 27 ( 28) is applied to the discharge pin 23 through the conductive metal tube 29. For example, a positive voltage is applied to one discharge pin 23 from two adjacent discharge pins 23 and a negative voltage is applied to the other discharge pin 23, or positive is applied to one discharge pin 23. Voltage and negative voltage can be applied alternately with pulses. Accordingly, while corona discharge is generated between the counter electrodes, positive/negative ions are generated from the discharge pin 23.

At the same time, high-pressure air flows into the air passage 12 from an air supply pipe (not shown) connected to the air inlet terminal 41 provided in the side cover 40 of the static eliminator body 10. The introduced high-pressure air flows into the insertion hole 24 of the support member 21 through the ventilation hole 26 formed in the annular bracket member 22, and discharge pins 23 along the air flow groove 25 formed on the inner surface thereof ).

Since the support member 21 is formed with an extended opening in the lower portion of the discharge pin 23, the discharged air can carry out a destaticizing operation by transporting positive/negative ions generated from the discharge pin 23 toward the whole body. have.

In performing such a destaticizing operation, when the destaticizing apparatus is close to the whole body, for example, at an ultra-short distance of about 10 mm, a phenomenon that the defrosting performance of the whole body is rather deteriorated occurs. It is possible to prevent the deterioration of the antistatic performance by interposing an electromagnetic wave blocking electrode capable of blocking the between the discharge structure 20 and the whole body. This effect of the present invention will be confirmed in the experimental examples described below.

Experimental Example

The static electricity elimination device used in this experiment is the ASG-A series corona ion discharge static electricity eliminator, which is the commercial product of the applicant, approximately: input voltage DC 24V, input current up to 300mA, discharge voltage 4.75kV ~ 5.5kV, output frequency 0.1Hz It has the specifications of ~100Hz, pulse alternating current application method. The distance to the object to be removed from static electricity was 10 mm, the pressure of the blowing air was 1 bar, and Trek 158 was used as a measurement tool.

A static electricity elimination operation is performed with a static electricity elimination device having a mesh-type electromagnetic wave blocking electrode 200 made of steel according to FIGS. 1A and 1B (referred to as “the present invention” in the table below), and electromagnetic wave blocking as a comparative example The operation of the static electricity elimination device without the dragon electrode 200 was performed together (represented as "Comparative Example" in the table below), and the results are shown in Table 1 below.

+offset
(+offset)
(V) -offset
(-offset)
(V) Offset width
(Offset PP)
(V) +Static time
(+Decay time)
(s) -Static time
(-Decay time)
(s) Average static elimination time
(Decay avr.)
(s) Example 13.3 -11.9 25.2 0.25 0.27 0.26 Comparative example 93.1 -128.1 221.2 12.3 12.76 12.53

11A and 11B show the results of the electromagnetic wave waveforms measured in the whole object. Here, FIG. 11A shows the electromagnetic wave waveform measured in the case where the electromagnetic wave blocking electrode 200 is not provided (comparative example), the effective voltage is 22.33 Vrms, and the maximum minimum voltage width is 59.7 Vp.p.

On the other hand, FIG. 11B shows an electromagnetic wave waveform measured when the electromagnetic wave blocking electrode 200 is provided (the present invention), wherein the effective voltage is 2.144 Vrms and the maximum minimum voltage width is 8.1 Vp.p.

As can be seen from the above, when performing the ultra-short distance static elimination operation, when the electromagnetic wave blocking electrode 200 according to the present invention is interposed between the static electricity elimination device and the whole, the voltage offset is greatly reduced, and Accordingly, it can be seen that the static elimination time is also significantly reduced.

Although the present invention has been specifically described through examples and accompanying drawings, the technical spirit of the present invention is determined by the matters set forth in the claims, and various modifications and variations are within the scope of the technical spirit of the present invention. There may be an equality example. Particularly, in the above-described embodiment, a static electricity elimination device having a specific configuration is described, but this is only an example conveniently presented to illustrate the present invention, and in addition to the configuration of the static electricity elimination device, discharge is induced by other methods and structures. / It should be understood that all of the static electricity elimination devices generating anions can be applied to the technical idea of the present invention.

10: static electricity elimination body 11: upper space
12: air passage 13: control
14: top cover 20: discharge structure
21: support member 22: annular bracket member
23: discharge pin 24: insertion port
25: air flow groove 26: vent
27: challenge plate 28: connecting screw
29: metal tube 30: connecting bracket
31: fixing bracket 40: side cover
41: air inlet terminal 100: static electricity elimination part
200,210,220,230,240,250,260,270,280: Electrodes for blocking electromagnetic waves
200S,210S,220S,230S,250S,260S,270S: Side part
200B,210B,220B,230B,240B,250B,260B,270B: Lower part
201: bending end G: sliding groove
OP: opening H: cleaning opening

Claims (11)

A static eliminator body having an air passage through which high pressure air is supplied;
A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And
A plurality of openings are formed to allow the positive/negative ions and high-pressure air to pass therethrough, and include an electromagnetic shielding electrode installed to cover at least a portion of the plurality of discharge structures,
The electromagnetic shielding electrode,
It is formed to be bent to have a side portion that covers at least a portion of both sides of the static elimination body, and a lower portion that covers at least a portion of the plurality of discharge structures,
A static electricity elimination device, characterized in that at least one cleaning opening hole is formed at a lower end of the electromagnetic wave blocking electrode. According to claim 1, The electromagnetic shielding electrode,
A static electricity elimination device comprising one of a mesh formed of a metal, a metal plate formed with a plurality of through holes, or a grill in which a metal wire is arranged in one direction. delete delete According to claim 1, The electromagnetic shielding electrode,
A static electricity elimination device comprising at least two sub-electrodes bent to have a side portion covering at least a portion of both sides of the static electricity elimination body and a lower portion covering at least a portion of the plurality of discharge structures. A static eliminator body having an air passage through which high pressure air is supplied;
A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And
A plurality of openings are formed to allow the positive/negative ions and high-pressure air to pass therethrough, and include an electromagnetic shielding electrode installed to cover at least a portion of the plurality of discharge structures,
The electromagnetic shielding electrode,
It is formed to be bent to have a side portion that covers at least a portion of both sides of the static elimination body, and a lower portion that covers at least a portion of the plurality of discharge structures,
The upper end of the side surface of the electromagnetic wave blocking electrode is bent toward the inside to form a bent end,
A static electricity elimination device, characterized in that a sliding groove in which the bending end portion is inserted and slidingly coupled is formed in a side surface of the static eliminator body. A static eliminator body having an air passage through which high pressure air is supplied;
A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And
A plurality of openings are formed to allow the positive/negative ions and high-pressure air to pass therethrough, and include an electromagnetic shielding electrode installed to cover at least a portion of the plurality of discharge structures,
The electromagnetic shielding electrode,
It is formed to be bent to have a side portion that covers at least a portion of both sides of the static elimination body, and a lower portion that covers at least a portion of the plurality of discharge structures,
The upper end of the side surface of the electromagnetic wave blocking electrode is bent toward the inside to form a bent end,
The bending end portion is a static elimination device, characterized in that slidingly coupled to both corners of the upper surface of the static eliminator body. According to any one of claims 1, 2, 5, 6 and 7, wherein the electromagnetic shielding electrode,
The static electricity elimination device, characterized in that attached to the static electricity elimination body by a fastening member. A static eliminator body having an air passage through which high pressure air is supplied;
A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And
A plurality of openings are formed to allow the positive/negative ions and high-pressure air to pass therethrough, and include an electromagnetic shielding electrode installed to cover at least a portion of the plurality of discharge structures,
The electromagnetic shielding electrode,
A side portion covering at least a part of one side of the static eliminator body; It is formed to be bent to have a lower end that covers at least a portion of the discharge structure,
The side portion is a static electricity elimination device, characterized in that coupled to the static elimination body within a predetermined range. A static eliminator body having an air passage through which high pressure air is supplied;
A plurality of discharge structures installed at a lower end of the static eliminator body to supply high-pressure air through the air passage, and generating positive/negative ions through discharge by the applied high voltage; And
A plurality of openings are formed to allow the positive/negative ions and high-pressure air to pass therethrough, and include an electromagnetic shielding electrode installed to cover at least a portion of the plurality of discharge structures,
The electromagnetic shielding electrode,
A side portion covering at least a portion of both side surfaces of the static eliminator body; It is formed to be bent to have a lower portion covering at least a portion of the plurality of discharge structures,
The static electricity elimination device, characterized in that the gap between the upper end of the side portion is set to be smaller than the width of the static eliminator body. According to any one of claims 1, 2, 5, 6, 7, 9 and 10, wherein the electromagnetic shielding electrode,
The static electricity elimination device, characterized in that provided independently to cover each of the plurality of discharge structures.

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