CN113606703A - Antistatic anion new trend system - Google Patents

Abstract

The invention discloses an antistatic anion fresh air system in the technical field of air purification, which comprises: a cold air filtration bin; the cold air electrostatic filtering bin is arranged at the top of the cold air filtering bin; the hot air filtering bin is arranged at the upper end of the cold air electrostatic filtering bin; the hot air electrostatic filtering bin is arranged at the bottom of the hot air filtering bin; the heat exchange pipeline is connected with the cold air electrostatic filtering bin and the hot air electrostatic filtering bin through pipelines; the cold air exhaust bin is connected with a cold air outlet of the heat exchange pipeline through a pipeline; the hot air exhaust bin is connected with the hot air outlet of the heat exchange pipeline through a pipeline, and the hot air exhaust bin can perform antistatic treatment on fresh air, prevent static accumulation and reduce the influence of static on a human body.

Description

Antistatic anion new trend system

Technical Field

The invention relates to the technical field of air purification, in particular to an antistatic anion fresh air system.

Background

The air purification is to provide the whole solutions of sterilization, dust reduction, haze removal, removal of harmful decoration residues, peculiar smell and the like aiming at various indoor environmental problems, improve the living and office conditions and promote the physical and mental health. The indoor environmental pollutants and pollution sources mainly comprise radioactive gases, mold, particulate matters, decoration residues, second-hand smoke and the like.

The fresh air system is a set of independent air processing system consisting of an air supply system and an air exhaust system and is divided into a pipeline type fresh air system and a pipeline-free fresh air system. The pipeline type fresh air system consists of a fresh air fan and pipeline accessories, outdoor air is purified by the fresh air fan and is led into a room, and indoor air is discharged through a pipeline; the ductless fresh air system is composed of a fresh air fan, and the fresh air fan is used for purifying outdoor air and guiding the outdoor air into a room. Relatively speaking, the pipeline type fresh air system is more suitable for being used in industrial or large-area office areas due to large engineering quantity, and the pipeline-free fresh air system is more suitable for being used in families due to convenient installation.

After the air is purified by the existing fresh air system, a certain amount of static electricity can be carried in the purified air, and the static electricity can affect a human body when being accumulated in a room.

Disclosure of Invention

The invention aims to provide an antistatic negative ion fresh air system, which solves the problems that after the air is purified by the conventional fresh air system in the background art, a certain amount of static electricity is carried in the purified air, and when a large amount of static electricity is accumulated in a room, the human body is influenced.

In order to achieve the purpose, the invention provides the following technical scheme: an antistatic anion fresh air system, comprising:

a cold air filtration bin;

the cold air electrostatic filtering bin is arranged at the top of the cold air filtering bin;

the hot air filtering bin is arranged at the upper end of the cold air electrostatic filtering bin;

the hot air electrostatic filtering bin is arranged at the bottom of the hot air filtering bin;

the heat exchange pipeline is connected with the cold air electrostatic filtering bin and the hot air electrostatic filtering bin through pipelines;

the cold air exhaust bin is connected with a cold air outlet of the heat exchange pipeline through a pipeline;

and the hot air exhaust bin is connected with a hot air outlet of the heat exchange pipeline through a pipeline.

Preferably, the cool air filtering bin includes:

a hollow bin body;

the two end covers are arranged at the left end and the right end of the hollow bin body in a left-right mode;

the air holes are uniformly formed in the side surfaces of the two end covers, and the inner cavities of the air holes are communicated with the inner cavity of the hollow bin body;

the partition plate is arranged at the middle end of the inner cavity of the hollow bin body, and the hollow bin body is divided into two symmetrical hollow cavities with equal volume through the partition plate;

the two filter plates are symmetrically arranged on the left side and the right side of the inner cavity of the hollow bin body and are distributed on the left side and the right side of the partition plate;

the two first fans are arranged on the left side wall and the right side wall of the partition board in a left-right mode;

the two second fans are symmetrically arranged on the left side and the right side of the top of the hollow cabin body and are distributed on the left side and the right side of the partition plate.

Preferably, the cold air electrostatic filter cartridge comprises:

a concave bin body;

the electrostatic dust removal filter screen is transversely arranged at the middle end of the inner cavity of the concave bin body;

the antistatic fiber net is installed on the top of the inner cavity of the concave bin body and the left and right side walls.

Preferably, the heat exchange tube includes:

a heat exchange conduit;

one end of the hot air inlet pipeline is mounted at the upper end of the right side face of the heat exchange pipeline, and the inner cavity of the hot air inlet pipeline is communicated with the inner cavity of the heat exchange pipeline;

one end of the cold air inlet pipeline is mounted at the lower end of the right side face of the heat exchange pipeline, and the inner cavity of the cold air inlet pipeline is communicated with the inner cavity of the heat exchange pipeline;

the heat exchange core is arranged at the middle end of the inner cavity of the heat exchange pipeline;

the hot air outlet pipeline is arranged at the upper end of the left side surface of the heat exchange pipeline, and the inner cavity of the hot air outlet pipeline is communicated with the inner cavity of the heat exchange pipeline;

the cold air outlet pipeline is arranged at the lower end of the left side face of the heat exchange pipeline, and the inner cavity of the cold air outlet pipeline is communicated with the inner cavity of the heat exchange pipeline.

Preferably, the cool air discharge bin includes:

an exhaust bin body;

the air outlet is formed in the middle end of the front surface of the exhaust bin body, and an inner cavity of the air outlet is communicated with an inner cavity of the exhaust bin body;

the sliding chute is arranged on the left side surface of the exhaust bin body;

the sliding block is arranged on the right side face of the exhaust bin body and is matched with the sliding groove;

one end of the air inlet pipeline is mounted at the middle end of the top of the exhaust bin body, and the inner cavity of the air inlet pipeline is communicated with the inner cavity of the exhaust bin body;

the negative ion generator is installed in the inner cavity of the exhaust bin body, and an air outlet in the negative ion generator corresponds to the air outlet.

Compared with the prior art, the invention has the beneficial effects that: the invention can perform antistatic treatment on fresh air, prevent electrostatic aggregation and reduce the influence of static electricity on human bodies, indoor or outdoor air is extracted through the cold air filter bin or the hot air filter bin, cold air is extracted from the cold air filter bin, hot air is extracted from the hot air filter bin, large particle dust in the extracted air is filtered through the cold air filter bin or the hot air filter bin and is conveyed into the cold air electrostatic filter bin and the hot air electrostatic filter bin after being filtered, the filtered air is subjected to electrostatic dust removal operation through the cold air electrostatic filter bin or the hot air electrostatic filter bin, fine particle dust in the air is taken out, the air subjected to electrostatic dust removal is subjected to electrostatic dust removal operation through the cold air electrostatic filter bin or the hot air electrostatic filter bin, and the air subjected to electrostatic dust removal enters the inner cavity of the heat exchange pipeline through the hot air inlet pipeline or the cold air inlet pipeline, the air entering the heat exchange pipeline is subjected to heat exchange treatment through a heat exchange core installed in the heat exchange pipeline, cold air is converted into hot air, the hot air is converted into cold air, the converted air is conveyed into a cold air exhaust bin or a hot air exhaust bin through a hot air exhaust pipeline or a cold air exhaust pipeline, the hot air exhaust pipeline conveys the hot air, the cold air exhaust pipeline conveys the cold air, the cold air exhaust bin or the hot air exhaust bin conveys the air subjected to electrostatic dust removal to carry out anion treatment, the air subjected to anion treatment is conveyed into indoor air through the cold air exhaust bin or the hot air exhaust bin, and the indoor air purification effect is achieved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a cold air filtration cartridge according to the present invention;

FIG. 3 is a schematic structural view of a cold air electrostatic filter cartridge according to the present invention;

FIG. 4 is a schematic view of a heat exchange tube configuration according to the present invention;

fig. 5 is a schematic structural view of the cold air exhaust bin of the present invention.

In the figure: 100 cold air filtering bins, 110 hollow bin bodies, 120 end covers, 130 air vents, 140 partition plates, 150 filter plates, 160 first fans, 170 second fans, 200 cold air electrostatic filtering bins, 210 concave bin bodies, 220 electrostatic dust removal filter screens, 230 antistatic fiber nets, 300 hot air filtering bins, 400 hot air electrostatic filtering bins, 500 heat exchange pipelines, 510 heat exchange pipelines, 520 hot air inlet pipelines, 530 cold air inlet pipelines, 540 heat exchange machine cores, 550 hot air outlet pipelines, 560 cold air outlet pipelines, 600 cold air exhaust bins, 610 exhaust bin bodies, 620 air outlets, 630 chutes, 640 sliders, 650 air inlet pipelines, 660 negative ion generators and 700 hot air exhaust bins.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides an antistatic anion fresh air system, which can perform antistatic treatment on fresh air, prevent static accumulation and reduce the influence of static on a human body, and please refer to fig. 1, which comprises the following components: the cold air filtering bin 100, the cold air electrostatic filtering bin 200, the hot air filtering bin 300, the hot air electrostatic filtering bin 400, the heat exchange pipeline 500, the cold air exhaust bin 600 and the hot air exhaust bin 700;

referring to fig. 1-2, the cool air filtering compartment 100 includes:

the hollow bin body 110 is mounted at the bottom of the wall;

the two end covers 120 are arranged at the left end and the right end of the hollow bin body 110;

a plurality of air holes 130 are uniformly formed on the side surfaces of the two end covers 120, and the inner cavities of the air holes 130 are communicated with the inner cavity of the hollow bin body 110;

the partition plate 140 is installed at the middle end of the inner cavity of the hollow bin body 110, and the hollow bin body 110 is divided into two symmetrical hollow cavities with equal volume through the partition plate 140;

the two filter plates 150 are symmetrically arranged at the left side and the right side of the inner cavity of the hollow bin body 110, the two filter plates 150 are distributed at the left side and the right side of the partition plate 140, and the air entering the inner cavity of the hollow bin body 110 is filtered through the filter plates 150 to filter large-particle dust in the air;

two first fans 160, one left fan 160 and one right fan 160, are installed on the left and right side walls of the partition 140, the first fan 160 installed on the left side pumps cold air indoors, and the first fan 160 installed on the right side pumps cold air outdoors;

the two second fans 170 are symmetrically arranged at the left and right sides of the top of the hollow bin body 110, the two second fans 170 are distributed at the left and right sides of the partition plate 140, and the air filtered by the filter plate 150 is extracted from the hollow bin body 110 through the second fans 170;

referring to fig. 1 to 3, the cold air electrostatic filtering bin 200 is installed on the top of the cold air filtering bin 100, and the cold air electrostatic filtering bin 200 includes:

the concave bin body 210 is arranged at the top of the hollow bin body 110, and the air filtered by the filter plate 150 is pumped into the inner cavity of the concave bin body 210 by the second fan 170;

the electrostatic dust removal filter screen 220 is transversely arranged at the middle end of the inner cavity of the concave bin body 210, the air entering the inner cavity of the concave bin body 210 is filtered through the electrostatic dust removal filter screen 220, and fine particle dust in the air is adsorbed through static electricity;

the antistatic fiber net 230 is installed on the top of the inner cavity and the left and right side walls of the concave bin body 210, and the air dedusted by the electrostatic dedusting filter screen 220 is subjected to static electricity removal treatment through the antistatic fiber net 230;

referring to fig. 1 again, the hot air filtering bin 300 is disposed at the upper end of the cold air electrostatic filtering bin 200, the structure of the hot air filtering bin 300 is the same as that of the cold air filtering bin 100, and the hot air filtering bin 300 extracts indoor or outdoor hot air and filters the extracted air;

referring to fig. 1 again, the hot air electrostatic filtering bin 400 is installed at the bottom of the hot air filtering bin 300, the structure of the hot air electrostatic filtering bin 400 is the same as that of the cold air electrostatic filtering bin 200, the hot air entering the hot air filtering bin 300 enters the inner cavity of the hot air electrostatic filtering bin 400 through the hot air electrostatic filtering bin 300, the air filtered by the hot air electrostatic filtering bin 300 is subjected to electrostatic dust removal work through the hot air electrostatic filtering bin 400, and the air subjected to electrostatic dust removal is discharged after being subjected to electrostatic elimination through the hot air electrostatic filtering bin 400;

referring to fig. 1, 2 and 4, a heat exchange duct 500 is connected to the cold air electrostatic filtering silo 200 and the hot air electrostatic filtering silo 400 through a duct, and the heat exchange duct 500 includes:

a heat exchange conduit 510;

one end of the hot air inlet pipeline 520 is installed at the upper end of the right side surface of the heat exchange pipeline 510, the inner cavity of the hot air inlet pipeline 520 is communicated with the inner cavity of the heat exchange pipeline 510, the hot air inlet pipeline 520 is connected with the hot air electrostatic filtering bin 400, and hot air processed by the hot air electrostatic filtering bin 400 enters the inner cavity of the heat exchange pipeline 510 through the hot air inlet pipeline 520;

one end of the cold air inlet pipe 530 is installed at the lower end of the right side surface of the heat exchange pipe 510, the inner cavity of the cold air inlet pipe 530 is communicated with the inner cavity of the heat exchange pipe 510, the other end of the cold air inlet pipe 530 is connected with the top of the concave bin body 210, the inner cavity of the cold air inlet pipe 530 is communicated with the inner cavity of the concave bin body 210, and cold air processed by the antistatic fiber mesh 230 enters the inner cavity of the heat exchange pipe 510 through the cold air inlet pipe 530;

the heat exchanger core 540 is installed at the middle end of the inner cavity of the heat exchange pipe 510, and performs heat exchange treatment on the air entering the inner cavity of the heat exchange pipe 510 through the heat exchanger core 540, so as to convert hot air into cold air and convert the cold air into hot air;

the hot air outlet pipe 550 is installed at the upper end of the left side surface of the heat exchange pipe 510, the inner cavity of the hot air outlet pipe 550 is communicated with the inner cavity of the heat exchange pipe 510, and hot air is discharged through the hot air outlet pipe 550;

the cold air outlet pipe 560 is installed at the lower end of the left side surface of the heat exchange pipe 510, the inner cavity of the cold air outlet pipe 560 is communicated with the inner cavity of the heat exchange pipe 510, and cold air is discharged through the cold air outlet pipe 560;

referring to fig. 1, 4 and 5, the cool air discharge bin 600 is connected to the cool air outlet of the heat exchange duct 500 through a duct, and the cool air discharge bin 600 includes:

the exhaust bin body 610 is installed at the bottom of the wall;

the air outlet 620 is arranged at the middle end of the front surface of the air exhaust bin body 610, and the inner cavity of the air outlet 620 is communicated with the inner cavity of the air exhaust bin body 610;

the chute 630 is arranged on the left side surface of the exhaust bin body 610, and the chute 630 and the exhaust bin body 610 are integrally processed;

the sliding block 640 is arranged on the right side surface of the exhaust bin body 610, the sliding block 640 is matched with the sliding groove 630, the sliding block 640 and the exhaust bin body 610 are integrally processed, the plurality of exhaust bin bodies 610 are combined together through the matching use of the sliding block 640 and the sliding groove 630, and the exhaust bin bodies 610 can be increased or decreased according to the indoor area;

one end of the air inlet pipeline 650 is installed at the middle end of the top of the exhaust bin body 610, the inner cavity of the air inlet pipeline 650 is communicated with the inner cavity of the exhaust bin body 610, the other end of the air inlet pipeline 650 is connected with the cold air outlet pipeline 560, the inner cavity of the air inlet pipeline 650 is communicated with the inner cavity of the cold air outlet pipeline 560, and cold air enters the inner cavity of the air inlet pipeline 650 through the cold air outlet pipeline 560;

the anion generator 660 is installed in the inner cavity of the exhaust bin body 610, an air outlet on the anion generator 660 corresponds to the air outlet 620, cold air entering the inner cavity of the air inlet pipeline 650 enters the inner cavity of the exhaust bin body 610 through the air inlet pipeline 650, the anion generator 660 installed in the inner cavity of the exhaust bin body 610 performs anion treatment on the cold air entering the inner cavity of the exhaust bin body 610, and the cold air after the anion treatment is discharged indoors through the air outlet 620;

referring to fig. 1 again, the hot air exhaust bin 700 is connected to the hot air outlet of the heat exchange duct 500 through a duct, performs an anion treatment on the hot air through the hot air exhaust bin 700, and discharges the anion-treated hot air into indoor air.

When the air purifier is used specifically, according to the environmental requirements, indoor or outdoor air is extracted through the cold air filtering bin 100 or the hot air filtering bin 300, cold air is extracted through the cold air filtering bin 100, hot air is extracted through the hot air filtering bin 300, large particle dust in the extracted air is filtered through the cold air filtering bin 100 or the hot air filtering bin 300, the filtered air is conveyed into the cold air electrostatic filtering bin 200 and the hot air electrostatic filtering bin 400, the filtered air is subjected to electrostatic dust removal operation through the cold air electrostatic filtering bin 200 or the hot air electrostatic filtering bin 400, fine particle dust in the air is taken out, the air subjected to electrostatic dust removal is subjected to electrostatic dust removal operation through the cold air electrostatic filtering bin 200 or the hot air electrostatic filtering bin 400, and the air subjected to electrostatic dust removal enters the inner cavity of the heat exchange pipe 510 through the hot air inlet pipe 520 or the cold air inlet pipe 530, the air entering the heat exchange pipeline 510 is subjected to heat exchange treatment through the heat exchange core 540 installed in the heat exchange pipeline 510, cold air is converted into hot air, the hot air is converted into cold air, the converted air is conveyed into the cold air exhaust bin 600 or the hot air exhaust bin 700 through the hot air exhaust pipeline 550 or the cold air exhaust pipeline 560, the hot air conveyed by the hot air exhaust pipeline 550 is hot air, the cold air conveyed by the cold air exhaust pipeline 560 is cold air, the air subjected to electrostatic dust removal is subjected to negative ion treatment through the cold air exhaust bin 600 or the hot air exhaust bin 700, the air subjected to negative ion treatment is conveyed into indoor air through the cold air exhaust bin 600 or the hot air exhaust bin 700, and the indoor air is purified.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the various features of the embodiments disclosed herein may be used in any combination, provided that there is no structural conflict, and the combinations are not exhaustively described in this specification merely for the sake of brevity and conservation of resources. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (5)

1. The utility model provides an antistatic anion new trend system which characterized in that: the method comprises the following steps:

a cold air filtration bin (100);

the cold air electrostatic filtering bin (200), wherein the cold air electrostatic filtering bin (200) is installed at the top of the cold air filtering bin (100);

a hot air filtration bin (300), the hot air filtration bin (300) being at the upper end of the cold air electrostatic filtration bin (200);

the hot air electrostatic filtering bin (400), wherein the hot air electrostatic filtering bin (400) is installed at the bottom of the hot air filtering bin (300);

the heat exchange pipeline (500) is connected with the cold air electrostatic filtering bin (200) and the hot air electrostatic filtering bin (400) through pipelines;

the cold air exhaust bin (600), the cold air exhaust bin (600) is connected with the cold air outlet of the heat exchange pipeline (500) through a pipeline;

the hot air exhaust bin (700), the hot air exhaust bin (700) is connected with the hot air outlet of the heat exchange pipeline (500) through a pipeline.

2. The antistatic anion fresh air system of claim 1, which is characterized in that: the cold air filtration cartridge (100) comprises:

a hollow cartridge body (110);

two end covers (120), wherein one end of each of the two end covers (120) is arranged at the left end and the other end are arranged at the right end and the left end of the hollow cabin body (110);

the air holes (130) are uniformly formed in the side surfaces of the two end covers (120), and the inner cavities of the air holes (130) are communicated with the inner cavity of the hollow bin body (110);

the baffle (140), the said baffle (140) is installed in the lumen middle end of the said hollow cabin (110), divide the hollow cabin (110) into two symmetrical hollow cavities of equal volume through the said baffle (140);

the two filter plates (150) are symmetrically arranged at the left side and the right side of the inner cavity of the hollow bin body (110), and the two filter plates (150) are distributed at the left side and the right side of the partition plate (140);

two first fans (160), wherein the two first fans (160) are arranged on the left side wall and the right side wall of the partition plate (140) in a left-right mode;

the two second fans (170) are symmetrically arranged at the left side and the right side of the top of the hollow cabin body (110), and the two second fans (170) are distributed at the left side and the right side of the partition board (140).

3. The antistatic anion fresh air system of claim 1, which is characterized in that: the cold air electrostatic filtration cartridge (200) comprises:

a concave cartridge body (210);

the electrostatic dust collection filter screen (220), the electrostatic dust collection filter screen (220) is transversely arranged at the middle end of the inner cavity of the concave bin body (210);

an antistatic fiber web (230), wherein the antistatic fiber web (230) is installed on the top of the inner cavity of the concave bin body (210) and the left and right side walls.

4. The antistatic anion fresh air system of claim 1, which is characterized in that: the heat exchange tube (500) comprises:

a heat exchange conduit (510);

one end of the hot air inlet pipeline (520) is installed at the upper end of the right side face of the heat exchange pipeline (510), and the inner cavity of the hot air inlet pipeline (520) is communicated with the inner cavity of the heat exchange pipeline (510);

one end of the cold air inlet pipeline (530) is installed at the lower end of the right side surface of the heat exchange pipeline (510), and the inner cavity of the cold air inlet pipeline (530) is communicated with the inner cavity of the heat exchange pipeline (510);

a heat exchanger core (540), wherein the heat exchanger core (540) is arranged at the middle end of the inner cavity of the heat exchange pipe (510);

the hot air outlet pipeline (550) is installed at the upper end of the left side face of the heat exchange pipeline (510), and the inner cavity of the hot air outlet pipeline (550) is communicated with the inner cavity of the heat exchange pipeline (510);

the cold air outlet pipeline (560) is installed at the lower end of the left side face of the heat exchange pipeline (510), and the inner cavity of the cold air outlet pipeline (560) is communicated with the inner cavity of the heat exchange pipeline (510).

5. The antistatic anion fresh air system of claim 1, which is characterized in that: the cold air exhaust bin (600) includes:

an exhaust bin body (610);

the air outlet (620) is formed in the middle end of the front surface of the exhaust bin body (610), and an inner cavity of the air outlet (620) is communicated with an inner cavity of the exhaust bin body (610);

a chute (630), the chute (630) being disposed on a left side surface of the exhaust bin body (610);

the sliding block (640) is arranged on the right side surface of the exhaust bin body (610), and the sliding block (640) is matched with the sliding groove (630);

one end of the air inlet pipeline (650) is installed at the middle end of the top of the exhaust bin body (610), and the inner cavity of the air inlet pipeline (650) is communicated with the inner cavity of the exhaust bin body (610);

the negative ion generator (660), install negative ion generator (660) the inner chamber of exhaust bin body (610), the gas outlet on negative ion generator (660) with air outlet (620) correspond.

Images