TWI587906B - Plasma mesh structure - Google Patents

Description

Plasma filter structure

The invention relates to a plasma filter structure for filtering air, in particular to a maximum surface direction of the negative electrode layer being perpendicular to the wind direction, so that the positive electrode mesh generates a large and thick high-voltage electric field corresponding to the negative electrode layer, and the air-charged particles are lifted. The material is adsorbed on the sieve and has a high efficiency of filtration.

Referring to FIG. 1 and FIG. 2 together, it is an electrostatic dust collecting structure of a conventional air filter, which comprises two first screens 1 , a second screen 2 , a plurality of positive electrode lines 3 , and a plurality of negative poles which are relatively parallel. The sheet 5 and the plurality of dust collecting plates 4 are disposed between the two negative electrode sheets 5 with a positive electrode line 3, and the positive electrode line 3 and the negative electrode sheet 5 generate a high-voltage electric field, so that the wind passes through the high-voltage electric field and is adsorbed to the plurality of dust collecting plates. 4 and the second filter screen 2, the dust collecting plate 4 and the negative electrode sheets 5 are longitudinally arranged between the first filter net 1 and the second filter net 2 to have a maximum board surface direction and the first The screen faces of the filter screen 1 and the second filter screen 2 are perpendicular to each other. In other words, the negative surface of the negative electrode sheets 5 and the dust collecting plates 4 are in the same direction as the wind direction.

In use, the wind (air) first enters through the first filter screen 1, and the high-voltage electric field generated by the positive electrode wire 3 and the negative electrode plate 5 causes the air to carry the particulate matter and adsorb to the dust collecting plate 4 and the second filter mesh. 2, in order to filter out harmful substances in the air, so that clean air is released from the second filter 2.

Since the negative electrode sheets 5 are arranged longitudinally between the first screen 1 and the second screen 2, the largest surface of the negative electrode sheet 5 is in the same direction as the wind direction, and the positive electrode line 3 corresponds to the negative electrode sheet 5. The generated electric field is small and weak, and the effect of charging the air is not significant, and the harmful substances attached to the dust collecting plate 4 and the second filter 2 are limited, causing the air released by the second filter 2, and It does not completely filter out bacteria, diseases, dust mites, allergens and odors in the air.

Accordingly, the main object of the present invention is to solve the problem that the electric field of the electrostatic dust collecting structure of the conventional air filter is small, and the air charging efficiency is not good, so that bacteria, diseases, dust mites, allergens and odors in the filtered air are caused. The effect is not ideal.

In order to achieve the above object, the present invention provides a plasma filter structure, comprising: a filter screen having a first surface and a second surface opposite to each other, the filter meshing with the first frame shape, the first a first positive electrode mesh is disposed adjacent to the first surface of the frame, and a first negative electrode layer is disposed away from the first surface, such that a wind direction is perpendicular to a maximum surface of the first negative electrode layer, and air passes through the first positive electrode mesh The high voltage electric field generated by the first negative electrode layer forms charged particulate matter and is adsorbed to the sieve.

The second frame is further disposed with a second frame adjacent to the first negative layer, and a second positive electrode is disposed adjacent to the first frame, and a second negative layer is disposed away from the first frame. The wind direction is perpendicular to the largest surface of the second negative electrode layer.

Wherein, the first frame is rectangular, the first positive electrode mesh is a wave-shaped steel wire, and the first positive electrode mesh is matched with the first frame by a wave-shaped side and perpendicular to the wind entering direction.

The first negative electrode layer is a porous mesh body, and a first outer frame is assembled on the outer circumference of the first negative electrode layer.

Wherein, the second frame is rectangular, the second positive grid is a wave-shaped steel wire, and the second positive mesh is matched with the second frame by a wave-shaped side and perpendicular to the air entering direction.

The second negative electrode layer is a porous mesh body, and a second outer frame is disposed on the outer circumference of the second negative electrode layer.

There is further included another filter, and the first frame is located between the two filters.

By the wind direction being perpendicular to the largest faces of the first and second negative electrodes, the first positive electrode of the first frame forms a large and thick high-voltage electric field corresponding to the first negative electrode layer, and the wind passes through a large-area high-voltage electric field. The air is charged with particulate matter. Similarly, the second positive electrode of the second frame also forms a large and thick high-voltage electric field corresponding to the second negative electrode layer, and the two high-voltage electric fields of the wind passing through the first and second frames are sufficient to improve the air charging capability. , greatly enhances the air-charged particulate matter and adsorbs to the filter.

Since the wind direction of the present invention is perpendicular to the largest faces of the first negative electrode layer and the second negative electrode layer, the first positive electrode mesh corresponding to the first negative electrode layer and the second positive electrode mesh corresponding to the second negative electrode layer can form a large and thick high voltage electric field. The air is passed through a large and thick two high-voltage electric field, and the particles can be fully charged and passed through the filter screen, so that the charged particulate matter in the air is adsorbed to the filter screen, so that the air released by the filter mesh can be completely filtered. I have been to Minami, dust mites, bacteria, mites, dust mites, and odors, etc., so that the clean air is filtered through the present invention.

The detailed description of the present invention and the technical description of the present invention are further illustrated by the embodiments, but it should be understood that these embodiments are for illustrative purposes only and are not to be construed as limiting.

Referring to FIG. 3 to FIG. 5, a first embodiment of a plasma filter structure according to the present invention includes: a first frame 10 and a filter screen 30. The filter frame 30 and the first frame 10 are arranged in parallel. The first frame 10 has a rectangular shape with a maximum surface perpendicular to the wind direction. The screen 30 is matched with the outer shape of the first frame 10 and has a first surface 31 and a second surface 32 opposite to each other. The first frame A first positive electrode net 11 is disposed adjacent to the first surface 31, and a first negative electrode layer 12 is disposed away from the filter net 30. The first positive electrode net 11 is bent back and forth by a steel wire to form a wave shape. A first side of the positive electrode web 11 is formed on the first frame 10 in a shape matching the shape of the first frame 10. The first negative electrode layer 12 is a porous mesh body, and the outer periphery of the first negative electrode layer 12 There is a first outer frame 13 that cooperates with the first frame 10.

Therefore, please refer to FIG. 4 again. Since the wind direction is perpendicular to the largest surface of the first negative electrode layer 12, the first positive electrode mesh 11 corresponds to the first negative electrode layer 12 to form a large-area high-voltage electric field, and the wind passes through. The thick high voltage electric field allows the particles to be fully charged, and the air carries charged particulate matter and adsorbs to the screen 30.

Referring to FIG. 6 and FIG. 7 , a second embodiment of the plasma filter structure of the present invention includes: a first frame 10 , a second frame 20 , and a screen 30 . The first frame 10 , The second frame 20 and the screen 30 are arranged in parallel. The first frame 10 and the second frame 20 are rectangular, and the maximum surface is perpendicular to the wind direction. The screen 30 is matched with the shape of the first frame 10 and has A first surface 31 and a second surface 32 opposite to each other, the first frame 10 is disposed adjacent to the first surface 31, and the first anode layer 12 is disposed away from the screen 30. The first positive electrode net 11 is formed by bending a steel wire back and forth to form a wave shape, and the first positive electrode net 11 is formed on the first frame 10 by a wave-shaped side of the first frame 10, and the first The negative electrode layer 12 is a porous mesh body, and the outer periphery of the first negative electrode layer 12 has a first outer frame 13 that is engaged with the first frame 10.

The second frame 20 is disposed adjacent to the first frame 10 in the direction of the first frame 10, and a second negative layer 22 is disposed away from the first frame 10. The second positive electrode 21 is bent back and forth by a steel wire. Forming a wave shape, the second positive electrode net 21 is formed on the second frame 20 in a shape of the second frame 20, and the second negative electrode layer 22 is a porous mesh body, and the first The outer circumference of the second negative electrode layer 22 has a second outer frame 23 that cooperates with the second frame 20.

Therefore, please refer to FIG. 7 again. Since the second positive electrode net 21 of the second frame 20 corresponds to the high voltage electric field corresponding to the second negative electrode layer 22, the wind passes through the high voltage electric field to cause the air to carry the charged particles, and the same The first positive electrode net 11 of the first frame 10 and the first negative electrode layer 12 also form a high-voltage electric field, and the wind passes through the two high-voltage electric fields of the first frame 10 and the second frame 20, and the charging time is longer, thereby greatly improving the air band. The charged particulate matter is adsorbed on the sieve 30 to thoroughly filter out harmful substances in the air.

Referring to FIG. 8 and FIG. 9 again, a third embodiment of the plasma filter structure of the present invention includes: a first frame 10 and two screens 30a, 30b, each of the screens 30a, 30b and the first frame. 10 is a parallel arrangement, the first frame 10 is rectangular, and the maximum surface is perpendicular to the wind direction. The first frame 10 is located between the two screens 30a, 30b, and the screen 30a is matched with the shape of the first frame 10. And having a first surface 31 and a second surface 32 opposite to each other, the first frame 10 is disposed adjacent to the first surface 31 in a direction of the first surface 31, and a first direction away from the screen 30a. The negative electrode layer 12 is formed by bending a steel wire back and forth to form a wave shape, and the first positive electrode mesh 11 is formed on the first frame 10 in a shape of the first frame 10 in a wave shape. The first negative electrode layer 12 is a porous mesh body, and the outer periphery of the first negative electrode layer 12 has a first outer frame 13 that is engaged with the first frame 10.

Therefore, please refer to FIG. 9 again. Since the wind direction is perpendicular to the largest surface of the first negative electrode layer 12, the first positive electrode mesh 11 corresponds to the first negative electrode layer 12 to form a large-area high-voltage electric field, and the wind passes through. The thick high-voltage electric field enables the particles to be fully charged. Since the wind first passes through the filter screen 30b, most of the larger particles in the air are filtered out, and then the first positive electrode net 11 of the first frame 10 is passed through. The high-voltage electric field formed by the first negative electrode layer 12 enables the fine particulate matter to be sufficiently charged and adsorbed to the sieve 30a to filter out harmful substances in the air.

Since the wind direction of the present invention is perpendicular to the largest faces of the first negative electrode layer 12 and the second negative electrode layer 22, the first positive electrode mesh 11 corresponds to the first negative electrode layer 12 and the second positive electrode mesh 21 corresponds to the second negative electrode layer 22. The area is large, and the electric field is formed to be large and thick. The charging time of the air passing through the two high-voltage electric field enables the particles to be fully charged, has a high-efficiency charging effect, fully reaches the charged particulate matter, and is adsorbed to the filter 30, so The air released by the filter 30 has completely filtered out allergens, dust mites, bacteria, sickness, dust mites, and odors, etc., so that the clean air is filtered through the present invention. It is greatly different from the electrostatic dust collecting structure of the filter air. The wind (air) is the distance between the two negative electrodes arranged in the longitudinal direction. The maximum surface of the negative electrode 5 is in the same direction as the wind direction, so that the positive electrode line 3 corresponds to The electric field generated by the negative electrode sheet 5 is small and weak, and the effect of charging the air is not significant, and the efficiency of the air-charged particulate matter adhering to the dust collecting plate is not good, so that the allergen and dust in the air cannot be effectively filtered out. The problem of cockroaches, bacteria, sickness, dust mites and odors, therefore, the present invention has a synergistic effect compared to the electrostatic dust collecting structure of the conventional air filter, and the bulletin and materials are checked before the application. No identical or similar structure was found to be published in the market, and an invention patent application was filed with the bureau in accordance with the provisions of the Patent Law.

The invention has been described above in terms of the preferred embodiments, and it should be understood by those skilled in the art that the present invention is not intended to limit the scope of the invention. It should be noted that variations and permutations equivalent to those of the embodiments are intended to be included within the scope of the present invention. Therefore, the scope of the invention is defined by the scope of the following claims.

(known)
1‧‧‧first filter
2‧‧‧Second filter
3‧‧‧ positive electrode line
4‧‧‧ dust collecting board
5‧‧‧Negative film (invention)
10‧‧‧ first frame
11‧‧‧First positive grid
12‧‧‧First negative layer
13‧‧‧ first frame
20‧‧‧ second framework
21‧‧‧Second positive grid
22‧‧‧Second negative layer
23‧‧‧ second frame
30, 30a, 30b‧‧‧ filter
31‧‧‧ first surface
32‧‧‧second surface

1 is an exploded perspective view of an electrostatic dust collecting structure of a conventional filtered air. 2 is a schematic view showing the combination of a conventional electrostatic dust collecting structure of filtered air. Figure 3 is an exploded perspective view of the first embodiment of the present invention. Fig. 4 is a schematic view showing the combination of the first embodiment of the present invention. Figure 5 is a combined perspective view of a first embodiment of the present invention. Figure 6 is an exploded perspective view of a second embodiment of the present invention. Figure 7 is a schematic diagram of the combination of the second embodiment of the present invention. Figure 8 is an exploded perspective view of a third embodiment of the present invention. Figure 9 is a schematic view showing the combination of the third embodiment of the present invention.

10‧‧‧ first frame

11‧‧‧First positive grid

12‧‧‧First negative layer

13‧‧‧ first frame

30‧‧‧ Filter

31‧‧‧ first surface

32‧‧‧second surface

Claims (6)

A plasma screen structure comprising: a filter screen having a first surface and a second surface opposite to each other; a first frame, the filter meshing with the first frame shape, the first frame being adjacent to the first frame a first positive electrode mesh is disposed in a direction of the first surface, and a first negative electrode layer is disposed away from the first surface, such that a wind direction is perpendicular to a maximum surface of the first negative electrode layer, and air passes through the first positive electrode mesh and the first a high voltage electric field generated by the negative electrode layer forms charged particulate matter and adsorbed to the filter mesh, and a second frame is adjacent to the first negative electrode layer, and a second positive electrode mesh is disposed in a direction of the second frame adjacent to the first frame. A second negative electrode layer is disposed away from the first frame such that the wind direction is perpendicular to the largest surface of the second negative electrode layer. The plasma screen structure of claim 1, wherein the first frame is rectangular, the first positive electrode is a wave-shaped steel wire, and the first positive electrode has a wave-shaped side The first frame fits and is perpendicular to the direction of wind entry. The plasma screen structure of claim 1, wherein the first negative electrode layer is a porous mesh body, and the outer periphery of the first negative electrode layer is provided with a first one combined with the first frame. Outer frame. The plasma screen structure of claim 1, wherein the second frame is rectangular, the second positive electrode is a wave-shaped steel wire, and the second positive electrode has a wave-shaped side The second frame fits and is perpendicular to the direction of air ingress. The plasma filter structure of claim 1, wherein the second negative electrode layer is a porous mesh body, and the outer periphery of the second negative electrode layer is provided with a second body that is combined with the second frame. Outer frame. The plasma screen structure of claim 1, wherein the filter screen structure further comprises another screen, the first frame being located between the two screens.