KR102062286B1 - Window screen with narrow plain channels for dust collection and insect-proof - Google Patents

Abstract

Disclosed is a dust screen that uses a corona discharge to charge dust in the air and then collects charged particles. In the dust screen according to the present invention, a plate-shaped electrode array in which a plurality of rectangular plate-shaped electrodes are disposed with a compact gap that can be insect-proof so as to form an air flow in the orthogonal direction with respect to the window frame to form a plate-shaped narrow channel. And a linear electrode array comprising a plurality of linear electrodes inserted between the plate electrodes of the plate electrode array and offset at the outdoor edge into which outside air is introduced, and applying a positive pole DC voltage to the plate electrode array, And a direct current power supply electrically connected to apply a negative voltage to the linear electrode array.

Description

Dust screen with integrated screen and integrated screen

The present invention relates to a dust screen, and more particularly, to a dust screen that collects charged particles after charging the dust in the air by using a corona discharge.

2. Description of the Related Art [0002] Many dust collecting insect screens using electric charges or static electricity due to discharge are known. Examples thereof are disclosed in Korean Unexamined Patent Publication No. 10-2016-0127265, Korean Unexamined Patent Publication No. 10-2014-0055555, and the like.

Korean Laid-Open Patent Publication No. 10-2016-0127265 discloses a net-shaped discharge portion to which a high voltage is applied, and a net-shaped discharge portion spaced from the discharge portion and electrically grounded to form an electric field therebetween. Disclosed is a insect screen assembly including a insect screen portion including a ground portion and a frame portion for fixing the insect screen portion. In order to collect dust in the insect screen assembly, corona discharge occurs in the discharge portion to charge the dust, and the dust collector must be charged with the opposite polarity to the charging dust. Corona discharge is a local discharge phenomenon that occurs only in a strong field when an unbalanced electric field is generated between both electrodes. When the surrounding air is ionized by an unbalanced electric field around the electrode, a micro current within several mA flows between the electrode and the surrounding ionized air and emits blue light. This is called corona discharge.

On the other hand, as disclosed in Korean Patent Application Laid-Open Publication No. 10-2016-0127265, in the case of a network structure in which two electrodes face each other, it is difficult to form an unbalanced electric field, and corona discharge is very difficult to occur at a low voltage within 1,000 V / DC. In order to obtain corona discharge in two opposing mesh structure as in the present invention, it is necessary to apply a voltage of at least 1,000 V / DC-3,000 V / DC. When using the electrode of the network structure, the air moves through the holes of the network (망 體) to move indoors and out. On the other hand, since the corona discharge occurs only between the closest gaps between the discharge part conductor and the ground part conductor, the discharge part meshes before and after the direction in which air travels, as in Korean Patent Application Laid-Open No. 10-2016-0127265. ) And the grounding network, and when the corona discharge is induced therebetween, the corona discharge is generated only between the conductors of the network and almost no corona discharge occurs in the hole of the network, which is a passage through which air passes. Do not. Therefore, dust passing through the hole of the electrode of the network structure is difficult to be charged. In addition, when the current collector is a network structure, the current collecting area is very narrow, and the passing time of the current collector surface of the charged dust collector is very short, so that the hole of the net mesh is drawn before the charged dust is drawn to the current collector surface (metal surface forming the mesh). Since passing through, even charged dust is difficult to collect.

Korean Laid-Open Patent Publication No. 10-2014-0055555 discloses a insect repellent window including an ionizing unit for ionizing dust in air and a dust collecting unit installed at the rear of the ionizing unit for collecting the ionized dust. Korean Laid-Open Patent Publication No. 10-2014-0055555, wherein the ionization portion includes a discharge electrode having a ground electrode and a discharge electrode having a positive electrode applied therebetween with a discharge electrode corresponding to the ground electrode, and the dust collector includes a pair of grounding electrodes. It is described as a dust collecting mesh having a positive electrode with a voltage applied between the electrode and the ground electrode. However, while dust is very insignificant due to positive charges and is easily charged by electrons, when using a discharge electrode having a positive electrode as in Korean Patent Laid-Open No. 10-2014-0055555, the emission of electrons is insignificant. The number of charged dust is small. According to the circuit configuration of FIG. 3 of Korean Patent Laid-Open Publication No. 10-2014-0055555 (which is called a positive corona discharge), even though a high pressure is applied, the number of electrons is very small and the number of positive charges is large around the discharge electrode. Because it does not contribute to the charging of dust, dust collection is not easy. In addition, as in Korean Patent Laid-Open Publication No. 10-2014-0055555, when the current collector is mesh-shaped, the current collecting area is very narrow, and the passing time of the current collector portion of the charged dust is very short, so that the charging dust is collected on the current collector surface ( Since it passes through the holes in the mesh before being drawn to the metal surface that makes up the mesh, even a small amount of charged dust is difficult to collect.

Korean Laid-Open Patent Publication No. 10-2016-0127265 (published date: 2016.11.03) Korean Laid-Open Patent Publication No. 10-2014-0055555 (Published Date: 2014.05.09)

The present invention has been made to solve the above problems of the dust collecting screen using the conventional discharge, the first problem to be solved by the present invention, can effectively induce corona discharge at a low DC voltage of 100V / DC-200V / DC To provide a dust screen.

The second problem to be solved by the present invention is to provide a dust screen that can charge most of the dust flowing from the outside.

A third problem to be solved by the present invention is to provide a dust collecting screen that can increase the amount of dust collection by increasing the dust collecting area, extending the movement path and transit time of the charged dust in the vicinity of the dust collecting surface.

The fourth problem to be solved by the present invention, the dust contained in the air flowing from the outdoor to the indoors by charging the dust (dust), the dust contained in the air discharged from the indoor to the outdoor without collecting (集塵) It is to provide a dust screen that can be discharged as it is.

The fifth problem to be solved by the present invention is to provide a dust screen that can perform the dust collection function and the insect repellent function at the same time without a separate mesh or mesh.

In the above-described problems of the present invention, a plurality of rectangular plate-shaped electrodes are disposed to form a plate-shaped narrow channel with a compact gap that can be insect-proof so as to form an air flow in the orthogonal direction with respect to the window frame. A linear electrode array comprising an array of electrodes and a plurality of linear electrodes inserted between the plate-shaped electrodes of the plate-shaped electrode array and an outer edge into which outside air is introduced, and a bipolar direct current to the plate-shaped electrode array. This can be solved by a dust screen having a plate-shaped narrow channel including a DC power supply that is electrically connected to apply a voltage and to apply a negative voltage to the linear electrode array.

The outer surface of the linear electrode is preferably disposed so as to overlap the outer surface of the plate-shaped electrode.

The cross-section of the linear electrode is preferably circular, elliptical or square, and the longest diagonal direction of the cross-section is disposed toward the plate-shaped electrode.

The present invention uses a direct current voltage, forms a non-uniform electric field using a plate-shaped electrode as an anode dust collecting electrode, a linear electrode as a cathode discharge electrode, and utilizes corona discharge generated in the electric field to form dust in the air. Is charged to the cathode, and the charged dust particles are separated and collected by the coulomb force on the plate-shaped electrode which is the anode dust collecting electrode.

As in the present invention, the linear electrodes that are arranged so closely as to be insect-proof (gap within 3 mm) to form an unequal electric field between the plate-shaped electrodes forming the air flow path are biased and inserted into the outdoor edge into which the outside air is introduced. When a positive pole voltage is applied to the plate electrode array and a negative pole voltage is applied to the linear electrode array, corona discharge can be induced even at a low DC voltage of 100 V / DC-200 V / DC, and all air passing through the screen is plate-shaped electrode. Passing through the corona discharge region between the and linear electrodes can charge most of the dust moving with the air. In addition, the dust flowing into the room from the outside is charged at the beginning of the channel and is attracted to the plate electrode while being collected along the wide plate electrode surface, so that the dust collection area is greatly increased compared to the mesh or mesh electrode, and the dust collection surface The movement path and the transit time of the charged dust in the vicinity are long, and not only the amount of dust collected per hour but also the total amount of collected dust before cleaning the insect screen can be greatly increased. In addition, according to the present invention, the dust contained in the air flowing from the outdoor to the indoor is charged in the plate electrode in the process of passing through the plate electrode charged at the channel inlet, but is contained in the air discharged from the indoor to the outdoor The dust is discharged to the outside after passing through the channel between the plate-shaped electrode without collecting dust and charged at the end, so that it does not accumulate on the plate-shaped electrode, which is the collecting plate. In addition, according to the present invention, while the space where the mosquito or the like can enter through the insect screen is a narrow space between the plate-shaped electrode and the linear electrode, the space is formed very densely like the hole of the insect screen and corona discharge occurs. Therefore, the insect-proof function can be performed together with the dust collecting function without a separate mesh or mesh.

1 is an exploded perspective view showing a plate electrode array and a linear electrode array separately of a dust screen having a dust screen integrated with a screen according to the present invention.
1 is a combined perspective view illustrating a plate electrode array and a linear electrode array of a dust screen having a dust screen integrated with a screen according to the present invention.
3 is a plan cross-sectional view of FIG. 2.
4 is a configuration diagram in which a DC power supply is coupled to a plate-shaped electrode array and a linear electrode array of a dust collecting screen having a dust collecting network integrated with a insect screen according to the present invention.
5 is an assembled perspective view illustrating a state in which a plate-shaped electrode array and a linear electrode array are assembled to a frame of a dust collecting net having a dust collecting net integrated with a insect screen according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a specific embodiment of a dust screen having a dust screen integrated with the insect screen according to the present invention.

As shown in Figs. 1 and 2, a feature of the present invention is that a plurality of rectangular plate electrodes 3 and a space between the plate electrodes 3 are arranged outdoors with spaces close enough to be insect repellent. It is to form a dust collecting network integrated with the insect screen using a plurality of linear electrodes (7) inserted in the side edge. As will be described later, the rectangular plate electrodes 3 function as collecting electrodes, and the plurality of linear electrodes 7 function as discharge electrodes.

The plurality of rectangular plate electrodes 3 are arranged to form an air flow in a direction orthogonal to the window frame. The plurality of rectangular plate-shaped electrodes 3 form a plate-shaped narrow channel 4 in each gap, which becomes a flow path through which air and dust pass. The plurality of rectangular plate electrodes 3 forming the channel 4 thus constitute a plate electrode array 1, and each plate electrode 3 is electrically shorted as will be described later. The linear plurality of linear electrodes 7 inserted into the channel 4 constitute a linear electrode array 5, with each linear electrode 7 electrically shorted as described below.

In the dust screen of the present invention, the linear electrodes 7 inserted into the channel 4, which are spaces between the plate electrodes 3, have a dust collecting surface of the plate-shaped electrodes 3. It is placed in a position where it can touch before contacting. In order for the charged dust to collect in the plate electrode 3 while passing through the channel 4, at an initial point entering the channel 4, the corona discharge generated between the linear electrode 7 and the plate electrode 3 is generated. Because it must be charged. At this time, in the state where the linear electrode 7 is inserted between the plate electrodes 3, the outer surface (outer boundary line) of the linear electrode 7 coincides with the outer surface (outer side surface) of the plate electrode 3. Overlapping is most advantageous for effective corona discharge and maximizing dust collection area.

In FIG. 3, a circular electrode is illustrated as a cross-section of the linear electrode 7, but an elliptical or square electrode capable of forming a peak with respect to the direction of the plate-shaped 3 electrode may be used. At this time, the direction in which the diagonal length of the cross section is longest is disposed toward the plate-shaped electrode. Linear electrodes of elliptical or rectangular cross section form an inequal electric field more easily, so corona discharge is also easily induced.

As shown in FIG. 3, the gap s between the plate-shaped electrodes 3 is 3 mm or less to function as a screen screen, and the diameter d or the cross-sectional diagonal length of the linear electrode inserted therebetween is 1.5 mm. Within In addition, the thickness 5 of the plate-shaped electrode 3 is equal to the diameter d of the linear electrode, and the width of the air traveling direction is set to 10 mm or less. Experimentally, as shown in FIG. 3, it was most preferable that the distance from the center of the linear electrode 7 to the dust collection surface of the plate-shaped electrode 3 was 1.2 mm, and the width | variety of the air traveling direction width of the plate-shaped electrode was 8 mm.

As shown in FIG. 4, the present invention includes a DC power supply device 9 having an A / D converter for converting a voltage of the commercial AC power supply 15 into direct current, and has a plate shape of the plate electrode array 1. An anode DC voltage is applied to the electrodes 3, and a cathode voltage is applied to the linear electrode 7 of the linear electrode array 5. To this end, the wirings 11a and 11b connecting the DC power supply 9 to the plate-shaped electrodes 3 and the linear electrodes 7 are prepared. The cathode side of the DC power supply 9 may be grounded. By doing so, the rectangular plate electrodes 3 function as collecting electrodes, and the plurality of linear electrodes 7 function as discharge electrodes to perform corona discharge.

As shown in FIG. 6, the plate-shaped electrode array 1 and the linear electrode array 5 are mounted in the frames 13a and 13b and installed in the window frame. The DC power supply 9 may be mounted or externally mounted in a window frame.

Referring to FIG. 3 again, when the outdoor air and dust flow into the room, the charge generated by the corona discharge generated between the linear electrode 7 and the plate electrode 7 may be charged with the negative electrode. As the dust passes through the channel 4, the dust is attracted to the surface of the plate-shaped electrode 3, which is the anode, by the coulomb force and is collected. On the other hand, when the indoor air and dust are discharged to the outside, the dust is charged by the electric charge generated by the corona discharge generated between the linear electrode 7 and the plate electrode 7 after passing through the channel 4 without charging. Since it is immediately discharged to the outside does not accumulate on the plate-shaped electrode (7).

As described above, according to the present invention, outside air flows into the linear electrode 7 capable of forming an unequal electric field between the plate-shaped electrodes 3 which are arranged so closely as to allow insects (within a gap of less than 3 mm) to form an air flow path. Inserted at the edge of the outdoor side, the positive electrode voltage is applied to the plate-shaped electrode array 1, and the negative electrode voltage is applied to the linear electrode array 5, and the corona discharge is performed even at a low DC voltage of 100 V / DC-200 V / DC. Since the air passing through the insect screen can only pass through the plate-shaped electrode (3) and the linear electrode (7), it is possible to charge most of the dust moving with the air. In addition, the dust flowing into the room from the outside is charged at the beginning of the channel 4, and is attracted to the plate electrode 3 while being collected along the wide plate electrode surface, so that the dust collecting area is larger than that of the mesh or mesh electrode. It greatly increases, and the movement path and the transit time of the charging dust in the vicinity of the dust collection surface are long, and the amount of dust collection per hour as well as the total dust collection before cleaning the insect screen can be greatly increased. In addition, according to the present invention, the dust contained in the air flowing from the outdoor to the indoor is charged at the channel inlet and collected in the plate-shaped electrode 3 in the process of passing through the plate-shaped electrode 3, but from indoor to outdoor The dust contained in the discharged air passes through the channel 4 between the plate electrodes without dust collection and is discharged to the outside after being charged at the end. Therefore, the dust is not accumulated on the plate electrode, which is the dust collecting plate. It can be greatly improved. In addition, according to the present invention, while the space where the mosquito or the like can enter through the insect screen is a narrow space between the plate-shaped electrode and the linear electrode, the space is formed very densely like the hole of the insect screen and corona discharge occurs. Therefore, the insect-proof function can be performed together with the dust collecting function without a separate mesh or mesh.

1: plate electrode array
3: plate-shaped electrode
4: Channel
5: linear electrode array
7: linear electrode
9 DC power supply
11a, 11b: wiring
13a, 13b: frame
15: Commercial AC Power

Claims (3)

In the dust collecting screen which collects the dust passing by the cathode by the plate-shaped electrode array and the linear electrode array connected to the DC power supply by collecting the negative electrode,
The plate-shaped electrode array is arranged with a narrow gap within 3 mm to form a narrow air flow channel to form an air flow in a direction perpendicular to the window frame, to allow air and dust to pass through, and to block insects and insects. Positive power is applied to allow the current to be collected on the wall,
The linear electrode array is disposed between each of the plate electrodes of the plate electrode array in a position where air and dust introduced into the room from the outside may contact the plate electrode wall before contacting the plate electrode wall, with the outside edge being introduced therein. Consisting of a plurality of linear electrodes, and a negative power is applied to charge dust to the negative electrode by corona discharge,
The dust flowing in from outside is discharged to the cathode at the outer edge of the plate electrode array in which the gap between the plate electrode array and the linear electrode array is formed, and then passes through the plate-shaped narrow channel of the plate electrode array. A dust screen having a dust screen integrated with a screen, characterized in that dust is collected on a wall of a plate-shaped electrode array charged with an anode.
The method of claim 1,
Dust collecting screen having a dust collecting net integrated with the screen, characterized in that the outer surface of the linear electrode is overlapping with the outer surface of the plate-like electrode disposed.
The method of claim 1,
Cross section of the linear electrode is a circular, oval or square, dust collecting screen having a dust collecting net integrated with the screen, characterized in that the longest direction of the diagonal length of the cross section is arranged toward the plate-shaped electrode.

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