CN219092374U - LTP honeycomb plasma dust collection module - Google Patents

Abstract

The utility model discloses an LTP honeycomb plasma dust collection module, which comprises a machine body, an air outlet arranged at the top of the machine body, a fan, an integrated module, an ionization module and an air inlet arranged at the bottom of the machine body, wherein the fan, the integrated module and the ionization module are sequentially arranged in the machine body from top to bottom; the integrated module comprises a first insulating shell and a micro-static filter screen; the first insulating shell is used for fixing the micro-static filter screen; the ionization module comprises a second insulating shell, a plasma generation area and a negative plate, wherein the plasma generation area and the negative plate are sequentially arranged inside the second insulating shell from top to bottom; a plurality of mounting beams are arranged in the plasma generation area, and a plurality of ionization needle points are arranged on each mounting beam. The utility model improves the dust collection efficiency, is convenient to clean, can stably generate a large amount of plasmas, reduces the energy consumption, prolongs the service life, improves the purification efficiency, solves the problems of ozone generation and spark arc discharge caused by static electricity in the prior art, scientifically designs the creepage distance, and avoids the hidden trouble of ozone spark arc discharge.

Description

LTP honeycomb plasma dust collection module

Technical Field

The utility model relates to an electrostatic dust collection and purification module, in particular to an LTP honeycomb plasma dust collection module.

Background

The plasma sterilizing technology is to decompose and break down negatively charged bacteria by using bipolar plasma electrostatic field, polarize and adsorb dust, then combine components such as drug impregnated active carbon, electrostatic net, photocatalyst catalytic device, etc. to perform secondary sterilizing filtration, and the treated clean air flows fast and circularly in a large amount, so that the controlled environment is kept in the standard of 'sterile clean room'.

In the prior art, an LTP honeycomb plasma integrated module is an electrostatic adsorption dust removal purification filter, gas molecules in air are ionized by utilizing a high-voltage direct-current electric field to generate a large number of electrons and ions, the electrons and the ions move towards two poles under the action of the electric field force, dust particles and bacteria in air flow are encountered in the moving process to charge the dust particles and the bacteria, the charged particles move towards opposite pole plates with the air flow under the action of the electric field force, after the air is ionized, the number of ions moving between poles is greatly increased due to chain reaction, the current between poles is sharply increased, the air becomes a conductor, high-strength voltage captures the attached bacteria particles, and instant electric conduction breakdown of cell walls consisting of proteins is achieved, so that the effect of killing bacteria, adsorbing and removing dust is achieved.

However, the LTP honeycomb plasma dust collecting module of the prior art has the following problems:

(1) The diameter of the filter holes of the filter screen of the honeycomb electrostatic adsorption device is smaller, so that the dust collection efficiency is poor, and the cleaning is difficult;

(2) The traditional electrostatic adsorption device for generating a large amount of ozone adopts high-voltage discharge, so that ozone is easy to generate, energy consumption is high, and service life is short.

Therefore, there is an urgent need to develop a device to solve the above problems.

Disclosure of Invention

The utility model overcomes the defects of the prior art and provides the LTP honeycomb plasma dust collection module.

In order to achieve the above purpose, the utility model adopts the following technical scheme: an LTP honeycomb plasma dust collection module comprising: the air outlet is arranged at the top of the machine body, and the fan, the integrated module and the ionization module are sequentially arranged in the machine body from top to bottom, and the air inlet is arranged at the bottom of the machine body;

the integrated module includes: a first insulating housing and a micro-static filter screen; the first insulating shell is used for fixing the micro-static filter screen;

the ionization module includes: the second insulating shell is sequentially arranged in the plasma generation area and the negative plate from top to bottom; a plurality of mounting beams are arranged in the plasma generation area, and a plurality of ionization needle points are arranged on each mounting beam.

In a preferred embodiment of the utility model, the integrated module and the ionization module are arranged in a completely coincident manner.

In a preferred embodiment of the present utility model, the plasma generating region is a hollow structure.

In a preferred embodiment of the present utility model, the micro-electrostatic filter screen is made of a polymer compound and graphene.

In a preferred embodiment of the present utility model, the filter holes of the micro-electrostatic filter screen are honeycomb polygonal holes.

In a preferred embodiment of the present utility model, the ionization needle tip is a tungsten metal steel needle.

In a preferred embodiment of the present utility model, the mounting beams are fixedly connected in the second insulating housing and are arranged in a linear array at equal distances in a horizontal direction.

In a preferred embodiment of the utility model, the ionization needle points are fixedly connected to the mounting beam and are distributed in an equidistant linear array.

The utility model solves the defects existing in the background technology, and has the following beneficial effects:

(1) The utility model provides an LTP honeycomb plasma dust collection module, which increases the diameter of a honeycomb polygonal filter hole of a micro-static filter screen, enlarges the contact area, simultaneously facilitates cleaning the filter screen and improves the dust collection efficiency.

(2) The utility model changes the wiring of the conductive circuit of the ionization module, reduces the voltage, thereby being capable of stably generating a large amount of plasmas, reducing the use energy consumption and improving the ionization efficiency.

(3) The ionization needle point adopts the metal tungsten steel needle, so that the reduction or failure of the purification efficiency caused by passivation of the steel needle using tungsten wires and common metal carbon as materials is avoided, the service life of the device is prolonged, and the purification efficiency of the device is ensured.

(4) The utility model adopts the micro-static technology, which overcomes the defects of ozone generation and spark arc discharge caused by traditional metal static electricity, improves the purification efficiency and prolongs the service life.

Drawings

The utility model is further described below with reference to the drawings and examples;

FIG. 1 is a perspective cutaway view of a preferred embodiment of the present utility model;

FIG. 2 is a block diagram of an integrated module and ionization module combination in accordance with a preferred embodiment of the present utility model;

FIG. 3 is an exploded view of an integrated module and ionization module of a preferred embodiment of the present utility model;

in the figure: 1. a body; 2. an air outlet; 3. an integration module; 31. a first insulating housing; 32. a micro-electrostatic filter screen; 4. an ionization module; 41. a second insulating housing; 42. a plasma generation region; 421. mounting a beam; 422. ionization needle tip 43, negative plate; 5. and an air inlet.

Detailed Description

The utility model will now be described in further detail with reference to the drawings and examples, which are simplified schematic illustrations of the basic structure of the utility model, which are presented only by way of illustration, and thus show only the structures that are relevant to the utility model.

Fig. 1 is a perspective view showing an overall cross-sectional structure of an LTP cellular plasma dust collecting module according to the present utility model.

The module comprises: the device comprises a machine body, an air outlet arranged at the top of the machine body, a fan, an integrated module, an ionization module and an air inlet arranged at the bottom of the machine body, wherein the fan, the integrated module and the ionization module are sequentially arranged in the machine body from top to bottom.

Fig. 2 shows a combined structure of an integrated module and an ionization module of an LTP cellular plasma dust collecting module according to the present utility model.

The integrated module comprises: a first insulating housing and a micro-static filter screen; the first insulating shell is used for fixing the micro-static filter screen;

the micro-electrostatic electric field in the filter screen grabs the charged dust particles, microorganisms, aerosol and the like, and adsorbs the charged dust particles, microorganisms, aerosol and the like on the surface of the channel, the surface of the channel is in the micro-electrostatic electric field, and bacteria, viruses and the like on the surface of the channel are inactivated under the condition of the micro-electrostatic electric field, so that the disinfection and purification of the ambient air are completed.

The ionization module includes: the second insulating shell is sequentially arranged in the plasma generation area and the negative plate inside the second insulating shell from top to bottom; a plurality of mounting beams are arranged in the plasma generation area, and a plurality of ionization needle points are arranged on each mounting beam.

It should be noted that the ionization module releases a large amount of high-concentration plasma, and the annihilation of positive and negative electrons generates a large amount of energy, so as to destroy the bacterial envelope and kill the cell nucleus. Compared with the prior art, the technology solves the problems of ozone generation and spark arc discharge caused by static electricity in the traditional technology, prolongs the service life of equipment, improves the working efficiency of the equipment and avoids safety risks.

Fig. 3 shows an exploded view of an integrated module and an ionization module of an LTP cellular plasma dust collection module of the present utility model.

In the utility model, the integrated module and the ionization module are arranged in a completely overlapped mode.

In the utility model, the plasma generation area is of a hollow structure.

In the utility model, the micro-electrostatic filter screen is made of a high molecular compound and graphene.

The micro-electrostatic filter screen is made of a polymer compound and graphene, so that a large amount of plasma can be stably generated, and the ozone content is smaller than a specified standard.

In the utility model, the filter holes of the micro-static filter screen are honeycomb polygonal holes.

It should be noted that the utility model provides an LTP honeycomb plasma dust collection module, which increases the diameter of a honeycomb polygonal filter hole of a micro-static filter screen, enlarges the contact area, simultaneously facilitates cleaning the filter screen, and improves the dust collection efficiency.

In the utility model, the ionization needle point adopts a metal tungsten steel needle.

The ionization needle point adopts the metal tungsten steel needle, so that the reduction or failure of the purification efficiency caused by passivation of the steel needle using tungsten wires and common metal carbon as materials is avoided, the service life of the device is prolonged, and the purification efficiency of the device is ensured.

In the utility model, the mounting beams are fixedly connected in the second insulating shell and are distributed in a horizontal equidistant linear array.

In the utility model, the ionization needle points are fixedly connected to the mounting beam and are distributed in an equidistant linear array.

When the air conditioner is used, indoor air enters the machine body from the air inlet, firstly, the air enters the ionization module, the ionization module adopts needle electrodes to discharge, the field of the ionization needle points is fixedly connected to the mounting beam and is distributed in an equidistant linear array, when the air conditioner is electrified, the ionization needle points can generate discharge to capture attached bacteria particles, and instant electric conduction breaks through cell walls formed by proteins, so that the effect of killing bacteria and absorbing and removing dust is achieved; meanwhile, gas molecules in the air are ionized to generate a large number of positive ions and electrons, and the electrons move to two poles under the action of an electric field force and touch dust particles and bacteria in the air flow in the moving process to charge the dust particles and bacteria. The utility model changes the wiring of the conductive circuit of the ionization module, reduces the voltage, thereby being capable of stably generating a large amount of plasmas, reducing the use energy consumption and improving the ionization efficiency.

The ionization needle point adopts the metal tungsten steel needle, so that the reduction or failure of the purification efficiency caused by passivation of the steel needle using tungsten wires and common metal carbon as materials is avoided, the service life of the device is prolonged, and the purification efficiency of the device is ensured. And solves the corona problem generated when particles in the air are polarized, thereby effectively controlling ozone.

Then the dust enters an integrated module, a micro-static filter screen is made of a high polymer compound and graphene, and the filter holes are honeycomb polygonal holes; the micro-electrostatic electric field in the filter screen grabs the charged dust particles, microorganisms, aerosol and the like, and adsorbs the charged dust particles, microorganisms, aerosol and the like on the surface of the channel, the surface of the channel is positioned in the micro-electrostatic electric field, and bacterial viruses and the like on the surface of the channel can be inactivated under the condition of the micro-electrostatic electric field, so that the disinfection and purification of the ambient air are completed.

The above-described preferred embodiments according to the present utility model are intended to suggest that, from the above description, various changes and modifications can be made by the person skilled in the art without departing from the scope of the technical idea of the present utility model. The technical scope of the present utility model is not limited to the description, but must be determined according to the scope of claims.

Claims (8)

1. An LTP honeycomb plasma dust collection module comprising: the machine body is provided with an air outlet at the top of the machine body, a fan, an integrated module and an ionization module which are sequentially arranged in the machine body from top to bottom, and an air inlet at the bottom of the machine body,

the integrated module includes: a first insulating housing and a micro-static filter screen; the first insulating shell is used for fixing the micro-static filter screen;

the ionization module includes: the second insulating shell is sequentially arranged in the plasma generation area and the negative plate from top to bottom; a plurality of mounting beams are arranged in the plasma generation area, and a plurality of ionization needle points are arranged on each mounting beam.

2. The LTP cellular plasma dust collection module of claim 1, wherein: the integrated module and the ionization module are arranged in a completely overlapped mode.

3. The LTP cellular plasma dust collection module of claim 1, wherein: the plasma generation area is of a hollowed-out structure.

4. The LTP cellular plasma dust collection module of claim 1, wherein: the micro-static filter screen is made of a high molecular compound and graphene.

5. The LTP cellular plasma dust collection module of claim 4, further comprising: the filter holes of the micro-static filter screen are honeycomb polygonal holes.

6. The LTP cellular plasma dust collection module of claim 1, wherein: the ionization needle point adopts a metal tungsten steel needle.

7. The LTP cellular plasma dust collection module of claim 1, wherein: the mounting beams are fixedly connected in the second insulating shell and are distributed in a horizontal equidistant linear array.

8. The LTP cellular plasma dust collection module of claim 7, wherein: the ionization needle points are fixedly connected to the mounting beam and are distributed in an equidistant linear array.

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