CN218864417U - Air treatment device - Google Patents

Abstract

The application discloses air treatment device belongs to air treatment technical field. The air treatment device comprises: the laser purification device is used for purifying air; the laser purification device includes: the purification device comprises a purification shell, a fan and a fan, wherein an air inlet and an air outlet and a purification air duct communicated with the air inlet and the air outlet are formed in the purification shell; the laser generator is connected to the purification shell and emits laser into the purification air channel, and the laser is reflected for multiple times on the surface layer of the reflector so as to sterilize the air in the purification air channel; the air treatment device further includes: the high voltage static source is connected with the purification casing electricity, and the high voltage static source provides high voltage static to the purification casing for the inside formation electric field that purifies the casing, with the electrified particulate matter in the adsorption air. This air treatment device adopts laser to air purification, has improved the purification rate.

Description

Air treatment device

Technical Field

The application relates to the technical field of air treatment, in particular to an air treatment device.

Background

The air treatment device has a purification function that a purification device is provided at an air inlet of the air treatment device or an ion generator is provided at an air outlet. The purification effect of the existing purification mode has many limitations and low purification efficiency. As the demand for air purification has gradually increased, the concept of using laser purification has been proposed.

However, the irradiation area of the laser beam is small, and a long time is required for application to purification of flowing air, resulting in increased power consumption and cost.

Disclosure of Invention

The application provides an air treatment device, increases the radiation scope of laser through laser multiple reflection, has improved the purification efficiency of air.

An air treatment device comprising: the laser purification device is used for purifying air; the laser purification device includes: the air purifier comprises a purifying shell, a fan and a fan, wherein an air inlet, an air outlet and a purifying air channel communicated with the air inlet and the air outlet are formed on the purifying shell; the laser generator is connected to the purification shell and emits laser into the purification air channel, and the laser is reflected for multiple times on the surface layer of the reflector so as to sterilize the air in the purification air channel; the air treatment device further includes: the high-voltage static source is electrically connected with the purifying shell and provides high-voltage static electricity for the purifying shell, so that an electric field is formed inside the purifying shell to adsorb charged particles in the air.

The application discloses air treatment device is owing to set up laser purifier, utilizes laser energy rapid sterilization to reach better purifying effect and purification efficiency.

In addition, in the laser purification device, the inner wall of the purification shell is set to be a mirror surface, so that the radiation range of laser in the purification air channel can be increased by utilizing the principle of mirror surface reflection, and flowing air can be ensured to be purified by air.

In addition, because the high-voltage static source is connected with the purification shell, the high-voltage static enables the laser purification device to form an electric field, and the high-voltage static adsorbs charged particles, so that the purification rate of air is improved.

In some embodiments, the exterior of the decontamination chamber is made of an electrically conductive material, and the high voltage electrostatic source is electrically connected to the exterior of the decontamination chamber.

In some embodiments, the inner wall of the purification shell is made of conductive material, and the high-voltage static electricity source is electrically connected with the inner wall of the purification shell.

In some embodiments, the high-tension static electricity source emits positive high-tension static electricity or negative high-tension static electricity.

In some embodiments, the purge housing includes a first shell portion, a second shell portion, and an intermediate shell portion connected between the first shell portion and the second shell portion; the material of the middle shell part is insulated; the high-voltage electrostatic source is electrically connected with the first shell part, and the second shell part is grounded.

In some embodiments, the purge housing includes a first shell portion, a second shell portion, and an intermediate shell portion connected between the first shell portion and the second shell portion; the material of the middle shell part is insulated; the high-voltage electrostatic source comprises a positive high-voltage electrostatic source and a negative high-voltage electrostatic source; the positive high-voltage electrostatic source is electrically connected with the first shell part, and the negative high-voltage electrostatic source is electrically connected with the second shell part.

In some embodiments, the reflector layer is an aluminum or tin foil.

In some embodiments, the reflector layer is made of metal or glass.

In some embodiments, the reflector layer is integrally formed with the purge shell.

In some embodiments, the mirror facing is bonded to an inner wall of the purge housing.

In some embodiments, the purge housing has an outer shape corresponding to the shape of the air chute.

In some embodiments, the laser light generated by the laser generator impinges on the reflector layer in an oblique manner when the reflector layer is planar.

Drawings

FIG. 1 illustrates a schematic diagram of an air treatment device according to some embodiments;

FIG. 2 shows a schematic diagram of a laser decontamination apparatus according to one embodiment;

FIG. 3 shows a schematic view of a laser purging device according to another embodiment;

FIG. 4 shows a schematic view of a laser purging device according to yet another embodiment;

FIG. 5 illustrates a schematic diagram of laser light reflection according to some embodiments;

FIG. 6 illustrates a schematic diagram of laser reflection according to further embodiments;

FIG. 7 shows a schematic diagram of a laser decontamination apparatus according to yet another embodiment;

FIG. 8 illustrates a schematic view of air deflection vanes in a clean air duct, according to some embodiments;

FIG. 9 is a schematic illustration of air deflection vanes in a clean air duct according to further embodiments;

fig. 10 illustrates a schematic view of a driving structure of a wind guide blade according to some embodiments;

FIG. 11 illustrates a schematic view of a light shield in a purge air duct in a blocking position, according to some embodiments;

FIG. 12 illustrates a schematic view of a light shield in a purge air duct in an open position according to some embodiments;

FIG. 13 is a schematic view of a clean air duct with a light barrier in an open position according to further embodiments;

FIG. 14 illustrates a schematic diagram of a driving structure of a light barrier according to some embodiments;

FIG. 15 illustrates a logical timing diagram for two lasers in an energy-saving purge mode according to some embodiments;

FIG. 16 illustrates a logical timing diagram for two lasers in a general purge mode according to some embodiments;

FIG. 17 illustrates a logical timing diagram for two lasers in a strong cleaning mode according to some embodiments;

FIG. 18 shows a schematic diagram of a laser purging device and a high-voltage electrostatic source according to some embodiments;

FIG. 19 shows a schematic diagram of a laser purging device and a high voltage electrostatic source according to further embodiments;

FIG. 20 shows a schematic diagram of a laser decontamination apparatus and a high voltage electrostatic source in accordance with still further embodiments;

FIG. 21 shows a schematic view of an air treatment device according to further embodiments;

in the above figures: 10. a housing; 11. an inlet; 12. an outlet; 13. an air duct; 20. a fan; 30. a laser purification device; 31. purifying the shell; 311. an air inlet; 312. an air outlet; 313. purifying the air duct; 314. a convex portion; 315. a first housing portion; 316. a second shell portion; 317. an intermediate shell portion; 32. a laser generator; 33. wind guide blades; 331. a first wind guide blade; 332. a second wind guide blade; 333. a rotating shaft; 34. a connecting rod; 341. a rack; 351. a motor; 352. a gear; 36. fixing the rod; 37. a light barrier; 371. an air intake light shielding plate; 372. a wind-out light shield plate; 38. a drive motor; 40. a high voltage electrostatic source; 41. a positive high voltage electrostatic source; 42. a negative high voltage electrostatic source; 100. an air handler; 110. and (7) an air pipe.

Detailed Description

To make the purpose and embodiments of the present application clearer, the following will clearly and completely describe the exemplary embodiments of the present application with reference to the attached drawings in the exemplary embodiments of the present application, and it is obvious that the described exemplary embodiments are only a part of the embodiments of the present application, and not all of the embodiments.

In the description of the present application, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are intended merely to facilitate the description and the simplified illustration, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the present application.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first", "second", may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless otherwise specified.

In the description of the present application, it should be noted that the terms "mounted", "connected", and "connected", unless otherwise specifically stated or limited, are to be construed broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

The air treatment device of the present application is described in detail below with reference to the accompanying drawings.

Referring to fig. 1, in which arrows in fig. 1 indicate a flow direction of air, an air treatment device according to an embodiment of the present application includes a cabinet 10 having an inlet 11 and an outlet 12, a blower 20 circulating air to the inside or outside of the cabinet 10, and a laser cleaning device 30 for cleaning air.

The cabinet 10 forms the general appearance of an air treatment apparatus, and has an inlet 11 and an outlet 12 formed therein, and air enters the cabinet 10 through the inlet 11, is treated, and is blown back into the room through the outlet 12. The housing 10 is further provided with an air duct 13 communicating the inlet 11 and the outlet 12, and air flows along the air duct 13 after entering the housing 11.

The fan 20 is disposed in the air duct 13. The fan 20 is used to blow air so that the air can flow from the inlet 11 to the outlet 12.

The air treatment device can be an air conditioner, a fresh air fan, a dehumidifier and the like. In any type of air treatment device, the air needs to be purified.

The laser purification device 30 is disposed in the air duct 13 and is used for sterilizing the air flowing through the air duct 13. Specifically, the laser purification device 30 is disposed at the inlet 11 or within the air duct 13 for sterilizing and purifying the air from the inlet 11.

In other embodiments, referring to FIG. 21, an air treatment device includes an air handler 100 and an air duct 110. An air duct 110 communicates between the air handler 100 and the room for delivering air therebetween.

In this embodiment, the air treatment device 100 may be a central air conditioner with an air duct, an air duct machine, a total heat exchanger, etc., and most of these air treatment devices are installed in a ceiling, and the air treatment device 100 communicates with the room through the air duct 110.

The air handler 100 has an air duct 13 therein, and the laser purification apparatus 30 may be disposed in the air duct 13.

In other implementations, the laser purging device 30 may be disposed within the air duct 110 for sterilizing the air flowing through the air duct 110.

Laser is a high-energy photon stream that causes absorption, excitation, oscillation, or ionization of biomolecules, resulting in the breaking or partial breaking of certain chemical bonds and even chromosome aberration. The mechanism of laser decontamination of microorganisms (e.g., bacteria, viruses, etc.) is as follows:

thermal effect: the laser is absorbed by bacteria or adhesive thereof to cause the temperature to rise rapidly and destroy the tissue structure of the bacteria; chemical effects: the laser can cause the chemical bond of cell molecules to be broken;

mechanical effect: the laser impact compresses and deforms the cells to rupture;

ionization effect: the laser generated plasma has a certain killing effect on bacteria.

Laser can realize short-time sterilization, so that better air purification effect can be realized by using laser sterilization.

Referring to fig. 2 to 4, the laser purifying apparatus 30 includes a purifying housing 31, and a laser generator 32 for emitting laser light.

The purge housing 31 forms the general appearance of the laser purge device 30. An air inlet 311 and an air outlet 312 are formed thereon, and with reference to fig. 1, air enters the housing 10 from the inlet 11, then enters the laser cleaning device 30 from the air inlet 311, is cleaned in the laser cleaning device 30, and then flows into the air duct 13 from the air outlet 312.

Therefore, the air inlet 311 is closer to the inlet 11 than the air outlet 312 in the flow path of the air, that is, the air inlet 311 is located upstream of the air outlet 312.

A cleaning air duct 313 is formed between the air inlet 311 and the air outlet 312 in the cleaning housing 31. The air entering the air inlet 311 flows along the clean air duct 313 to the air outlet 312.

The laser generator 32 can be connected in the air purifying duct 313 by means of screws, fasteners or adhesives, etc., and the laser generator 32 emits laser light to the outside, so that air purification is realized by the laser light.

Since the laser beam generated by the laser generator 32 is thin and has strong directivity, the area to which the laser beam is radiated is small, and only a small portion of air in the air duct can be purified. In order to improve the purification rate, in some embodiments of the present application, the inner wall of the purification housing 31 is designed to be a mirror surface, and the reflection of the laser beam inside the purification air duct 313 is increased by the mirror surface. Specifically, the inner wall of the purification casing 31 may be provided with a mirror surface layer, enhancing reflection by the mirror surface.

The air treatment device of the application, owing to set up laser purifier 30 in it, utilizes the characteristics that laser energy disinfects fast to reach better purifying effect and purification efficiency.

Moreover, in the laser purification device 30, since the inner wall of the purification casing 31 is set to be a mirror surface, the radiation range of the laser in the purification air duct 313 can be increased by using the principle of mirror reflection, and it is ensured that the flowing air can be purified by air.

According to some embodiments of the present application, the mirror layer may be formed by disposing aluminum foil, tin foil, or the like on the inner wall of the purification housing 31, which may be a smooth mirror material that can reflect light.

The mirror surface material may be adhesively attached to the inner wall of purge housing 31. Or the processing technology is simple and the cost is low.

The laser purification apparatus 30 has an outer shape corresponding to the shape of the air duct 13. For example, the cross section of the air duct type air conditioning indoor unit is mostly rectangular, and then the purifying shell 31 of the laser purifying device 30 is rectangular; the cross section of the air duct of the fresh air fan is circular, so that the purifying shell 31 of the laser purifying device 30 is cylindrical; the usable space inside a large-sized centralized heat exchange air conditioning equipment (such as an AHU) is large, so the shape of the laser purification device 30 is not limited, and the laser purification device can be spherical, rectangular or cylindrical.

Illustratively, referring to fig. 2, the laser purification apparatus 30 is a sphere, and the air inlet 311 and the air outlet 312 are disposed at two ends of the sphere having the same diameter. The laser generator 32 is positioned on one side of the spherical wall between the air inlet 311 and the air outlet 312; in addition, the number of the laser generators 32 may be one, or may be increased at an opposite position or a side position.

The laser light emitted from the laser generator 32 is continuously reflected within the sphere, so that the exposure time of the air flowing from the air inlet 311 to the air outlet 312 is prolonged.

Illustratively, referring to fig. 3, the laser purification apparatus 30 has a cylindrical shape, and an air inlet 311 and an air outlet 312 are respectively disposed on two circular surfaces of the cylindrical shape. The laser generators 32 are located on the side wall of the cylinder, and the number of the laser generators 32 may be one, or may be increased in opposite positions or in a side position.

The laser light generated by the laser generator 32 is continuously reflected on the sidewall of the cylinder, so that the exposure time of the air flowing through the air inlet 311 to the air outlet 312 is prolonged.

Illustratively, referring to fig. 4, the laser purification apparatus 30 is a rectangular parallelepiped, and an air inlet 311 and an air outlet 312 are respectively disposed on a set of opposite surfaces of the rectangular parallelepiped. The other four sides except the side where the air inlet 311 and the air outlet 312 are located are reflective surfaces, and the laser generator 32 may be disposed on the reflective surfaces, and in addition, one or more laser generators 32 may be disposed.

The laser generated by the laser generator 32 is reflected on the reflecting surface, so that the exposure time of the air flowing to the air outlet 312 through the air inlet 311 is prolonged.

In some embodiments of the present application, referring to fig. 5, the inner wall of the purification shell 31 is a concave curved surface, so that the laser can be reflected on the concave curved surface to concentrate the reflected light in the purification air duct, which is beneficial to improving the laser purification effect and purification efficiency.

When the purifying shell 31 is a cylinder or a sphere, the inner wall thereof is directly a concave curved surface, and the concave curved surface thereof can be directly utilized; when the purge case 31 has a rectangular parallelepiped shape, the inner wall thereof may be formed into a concave curved surface.

In some embodiments of the present application, referring to fig. 6 and 7, the inner wall of the purge housing 31 has a plurality of protrusions 314 thereon. Thus, when the laser is irradiated onto the convex portion 314, the diffuse reflection is easily formed, and the light irradiation area is increased.

The projections 314 may be distributed over the reflecting surface at predetermined intervals so that the laser beam is irradiated without dead space inside the purge case 31.

The outer surface of the convex portion 314 is a spherical surface, which can increase the reflection range of light.

The convex part 314 and the purifying shell 31 can be integrally formed and manufactured, and the manufacturing process is simple and the cost is low.

In some embodiments of the present application, referring to fig. 8-10, where arrows indicate air flow paths, the laser purging device 30 further comprises air guiding blades 33. The air guiding blade 33 is arranged in the purifying air channel 313 and extends from the side wall of the purifying air channel 313 to the center direction, so that the air guiding blade 33 blocks the air, the flow direction of the air in the purifying air channel 313 is changed, the flow path of the air is prolonged, the flowing time of the air in the purifying air channel 313 is prolonged, namely, the exposure time is increased, and the purifying rate of the air is improved.

According to some embodiments of the present application, the plurality of wind guide blades 33 are arranged at intervals in the flow direction of the air. Thus, the flow direction of the air can be changed for a plurality of times, and the flow path of the air is prolonged.

In some embodiments, with particular reference to fig. 8, the purge air chute 313 has opposing first and second sidewalls; the air guide blade 33 includes a first air guide blade 331 and a second air guide blade 332, the first air guide blade 331 extends from the first side wall toward the center, and the second air guide blade 332 extends from the second side wall toward the center. The first air guiding vanes 331 and the second air guiding vanes 332 are arranged in a staggered manner from the air inlet 311 to the air outlet 312. In this way, the flow direction of the air is changed by the first air guide blade 31 and the second air guide blade 332 in sequence a plurality of times during the air flow, the flow path is further extended, the exposure time is further increased, and the cleaning rate is further improved.

In addition, along the flow direction of the air, the first air guide blades 331 are arranged at intervals, the second air guide blades 332 are arranged at intervals, and the first air guide blades 331 and the second air guide blades 332 form a labyrinth path in the clean air duct 313, so that the flow path of the air is extended.

In some embodiments, referring to fig. 9 in particular, the air guiding blade 33 is disposed obliquely in the purge air duct 313, and the air guiding blade 33 is inclined toward the air outlet 312 from the sidewall of the purge air duct 313 toward the center. In this way, the inclined arrangement of the air guide blades 33 can reduce the wind resistance to the air while extending the air flow path.

In some embodiments, the air guide blade 33 may be provided swingably. The swing angle of the air guide blade 33 can be used to satisfy both the requirements of the purification rate and the wind resistance.

For example, when the air guiding blade 33 swings to 90 °, the air flow path is relatively long, the purification rate is high, but the wind resistance is large, and when it is necessary to mainly improve the air purification rate, the air guiding blade 33 can be controlled to swing to this angle (90 °); when the air guiding blade 33 swings to be approximately parallel to the air flow direction, the wind resistance is minimum, however, the flow path is not prolonged, the purification rate is relatively low, and when a large wind speed is required, the air guiding blade 33 can be controlled to swing to a small angle or even 0 degrees.

The air guide blades 33 are rotatably connected to the purification housing 31, and the plurality of air guide blades 33 are interlocked with each other by the link 34, so that the air guide blades 33 swing together with the link 34 when the link 34 moves.

The first driving member is connected to the link 34 for driving the link 34 to move. Specifically, referring to fig. 10, the first drive member may be in the form of a motor and rack and pinion arrangement. The connecting rod 34 is provided with a rack 341, the rack 341 is meshed with the gear 352, and when the gear 352 is driven by the motor 351 to rotate, the gear 352 drives the rack 341 to move, so that the connecting rod 34 moves.

In other embodiments, the first driving member may also be a pneumatic cylinder with a telescopic rod, an electric push cylinder or a hydraulic cylinder, etc. The telescopic rod is connected with the connecting rod 34, and the movement of the connecting rod 34 is realized through the extension and contraction of the telescopic rod.

According to the embodiment of the present application, the laser purification apparatus 30 further includes a fixing rod 36, the fixing rod 36 is fixedly connected to the inner wall of the purification air duct 313, a mounting hole is formed in the fixing rod 36, and the rotating shaft 333 on the air guiding blade 33 is fitted in the mounting hole. When the link 34 moves the air guide blade 33, the rotating shaft 333 rotates relative to the fixing rod 36.

The moving distance of the connecting rod 34 can control the swing angle of the wind guiding blade 33.

In some embodiments of the present application, since the swing angle of the air guiding blade 33 may affect the cleaning efficiency of the laser cleaning device 30, the air cleaning device may have a plurality of cleaning modes, such as a general cleaning mode, a strong cleaning mode, and the like, according to the different cleaning efficiencies.

The controller can control the air guide blades 33 to swing to corresponding angles according to different purification modes. For example, the air guide blade 33 swings to a preset angle α in the normal purge mode, and the air guide blade 33 swings to a preset angle β in the strong purge mode. The swing angle is an included angle between the air guide blade 33 and the extending direction of the purifying air duct 313, and alpha is smaller than beta. The air guide blade 33 has a better effect of extending the air flow path at a larger swing angle, and has higher purification efficiency.

In addition, different wind speeds can be correspondingly set in different purification modes. The controller controls the wind speed of the fan 30 according to different purification modes. For example, the fan corresponds to a wind speed a in the strong purification mode, a wind speed b in the general purification mode, and a wind speed c in the normal mode. B is more than or equal to a and less than c, the smaller the wind speed, the slower the flow speed of air in the purification air channel, the longer the exposure time, and the higher the purification rate; changing an idea, when a user selects a strong purification mode, the user is more concerned about the purification effect of the air, and at the moment, the wind speed is low, so that the purification requirement can be met preferentially; when the user selects the normal mode, the user is more attentive to the basic performance, and at the moment, the wind speed is high, so that the requirement of the user on the basic performance can be met preferentially.

The working mode, the swing angle of the air guide blade 33, and the wind speed are stored in the memory in a one-to-one table form, and after receiving the working mode selected by the user, the controller controls the air guide blade 33 to swing to the corresponding angle according to the table, and controls the fan 30 to operate at the corresponding wind speed.

The purification modes of different degrees enable the air treatment device to be more intelligent, and the purification requirements under different air pollution degrees are met.

In some embodiments, the swing angle of the air guide blade can also be controlled in linkage with the air volume, that is, the controller is used for adjusting the air guide blade to a corresponding angle according to the wind gear selected by the user.

Specifically, when the controller receives a high wind gear selected by a user, the air guide blade is adjusted to swing to a preset angle alpha 1; when the controller receives that a user selects a low wind gear, the swing of the air guide blade is adjusted to an angle beta 1, and alpha 1 is smaller than beta 1. The swing angle of the air guide blade is small when the wind gear is high, so that the air guide blade reduces the blockage of wind, and the requirement of a user on high wind volume is met preferentially; the swing angle of the air guide blade is large in the low wind gear, so that the air guide blade is additionally provided with a wind block, the flow path of air is prolonged, and the exposure time is prolonged. The user low profile indicates that the demand for basic performance is not high and purging may be prioritized.

In some embodiments, for convenience of description, both the intake opening 311 and the outtake opening 312 are referred to as an air opening.

Referring to fig. 11 to 13, the laser purification apparatus 30 may include a light barrier 37, and the light barrier 37 is disposed at the wind gap for blocking the laser and preventing the laser from leaking.

In an example, the position of the laser generator 32 in the purification air duct 313 may be determined first, and then the reflection path of the laser in the purification air duct 313 is calculated according to the reflection rule of the laser, so that the outward emission range of the laser at the air outlet can be known, and the light barrier 37 is disposed corresponding to the outward emission range, so as to block the laser and prevent the laser from leaking out.

In another example, the minimum air volume performance requirement of the product may be confirmed, the shielding area of the light barrier 37 to the purge air duct 313 is confirmed through the minimum air volume, and then the position range of the light barrier 37 is used as a point on the laser reflection path to reversely deduce the position of the laser generator 32 on the purge air duct 313. The mode can ensure the requirement of minimum air quantity while ensuring that the laser does not leak.

According to an embodiment of the application, the light barrier 37 is movable between a shielding position, in which the air opening is partially shielded, and an open position, in which the air opening is fully open.

When the laser generator 32 is in operation, the light barrier 37 is in the blocking position (fig. 11), blocking laser light from leaking; when the laser generator is not operating, the light barrier 37 is in the open position (fig. 12, 13), which avoids that it affects the wind speed.

In some embodiments, the light barrier 37 is translatably movable between the blocking position and the open position.

When the light barrier 37 moves towards the direction close to the tuyere, the tuyere is shielded, and when the light barrier 37 moves towards the direction far away from the tuyere, the tuyere is opened.

The movement of the light barrier 37 is effected by a second drive. The structure of the second driving member is the same as that of the first driving member, and the description thereof is omitted.

The light barrier 37 specifically includes an air inlet light barrier 371 disposed at the air inlet 311, and an air outlet light barrier 372 disposed at the air outlet 312.

For example, in fig. 11, the intake air blocking plate 371 blocks the lower portion of the intake opening 311 when moving upward, and blocks the upper portion of the outlet opening 312 when moving downward; in fig. 12, the intake opening 311 is opened when the intake shutter 371 moves downward, and the exhaust opening 312 is opened when the exhaust shutter 372 moves upward.

In some embodiments, referring specifically to FIG. 13, the light barrier 37 is rotatably movable between a blocking position and an open position.

When the light barrier 37 rotates to the air inlet, part of the air inlet can be shielded, and when the light barrier 37 rotates to the direction far away from the air inlet, the air inlet is completely opened.

Referring to fig. 14, the light barrier 37 can be rotated by a driving motor 38, a motor shaft of the driving motor 38 is connected to the light barrier 37, and the driving motor 38 rotates to rotate the light barrier 37.

Illustratively, when the light barrier 37 is rotated to be parallel to the air flow direction, it is not shielded from the air opening, and is in the open position; when the light barrier 37 is rotated to a position where the tuyere is perpendicular to the air flow direction, a part of the tuyere is shielded and is in a shielding position.

According to the embodiment of the application, when the light barrier 37 is in the open position, it is located in the purge air duct 313, which can reduce the occupied space of the light barrier 37, so that the product structure is more compact.

In some embodiments of the present application, the laser purification apparatus 30 may further include an air quality sensor.

The air quality sensor is disposed upstream of the air inlet 311 or at the air inlet 311 with reference to the flow path of the air.

Taking the laser purification device as an example, the air quality sensor may be disposed at the inlet 11, or between the inlet 11 and the air inlet 311, and is configured to detect the air quality a of the inlet air.

The controller is used for controlling the intermittent starting of the laser generator 32 and controlling the on-off duration of the laser generator according to the air quality a.

Because laser generator 32 has life, this application carries out intermittent type nature to laser generator 32 and opens the life that can prolong laser generator 32, satisfies the complete machine and uses the requirement to the life-span.

And intermittent opening is also favorable for heat dissipation of the laser generator, so that the normal performance of the product is ensured, and the service life of the laser generator is prolonged.

In addition, the intermittent starting can also reduce the power consumption, and the energy-saving advantage is achieved.

In some embodiments, a laser generator 32 is provided within the laser purification apparatus 30. Every time the laser generator 32 is turned on T _ON Duration, then turn off T _OFF A duration;

when a is less than a1, controlling the laser generator to shut down; under this condition, it is demonstrated that the air quality is relatively good and no purification is required, and therefore, the laser generator is turned off.

When a1 is more than or equal to a and less than a2, entering an energy-saving purification mode, wherein the starting time and the shutdown time of the laser generator meet the following requirements: t is a unit of _ON ＜T _OFF (ii) a For example, n can be set ₁ ×T _ON ＝T _OFF Wherein n is ₁ Is more than 1; under the condition, the air pollution is relatively light, and the requirement of air purification can be met under the condition of short opening time, so the opening time T of the laser generator _ON Less than its turn-off time period T _OFF 。

When a2 is more than or equal to a and less than a3, entering a general purification mode, wherein the starting time and the shutdown time of the laser generator meet the following conditions: t is a unit of _ON ＝T _OFF (ii) a Under the condition, the air pollution degree relatively tends to a medium degree, and the time for starting the laser generator is equal to the time for shutting down the laser generator, so that the air purification requirement can be met.

When a is more than or equal to a3, entering a strong purification mode, wherein the starting time and the shutdown time of the laser generator meet the following requirements: t is _ON ＞T _OFF (ii) a For example, T can be set _ON ＝n ₂ T _OFF Wherein n is ₂ Is more than 1; under the condition, the serious air pollution is shown, the laser generator needs to be started for a long time to achieve a good purification effect, and therefore the starting time is long T _ON Greater than the shutdown duration T _OFF 。

Wherein, T _ON 、a1、a2、a3、n ₁ 、n ₂ Is a preset value, and a1 < a2 < a3.

In the above description, T _ON 、T _OFF For variable parameters, in different cleaning modes, T _ON 、T _OFF May be assigned different preset values.

In some embodiments, two or more laser generators are provided in the laser purification apparatus 30, and different laser generators can be operated alternately.

The laser generators are turned on and off once to form a period, and the plurality of laser generators alternately work according to the period.

For example, the laser generator has m, m being an integer of not less than 2, each represented by the symbol Q ₁ 、Q ₂ 、......Q _m And (4) showing. During the first period by Q ₁ Act, Q ₂ 、.....Q _m Shutdown, from Q during the second cycle ₂ Act, Q ₁ 、Q ₃ 、......Q _m Shut down, and so on until recycle to Q ₁ 。

Referring to fig. 15 and 16, in the energy saving purge mode or the normal purge mode, for example, with m =2, Q is set to be Q in the first cycle ₁ Turn on T _ON1 Closing T _OFF1 Then rotated to Q ₂ For a second period, Q ₂ Turn on T _ON2 Closing T _OFF2 (ii) a Then rotated to Q ₁ Performing a third cycle, thereby cycling; at Q ₁ In the period of action, Q ₂ Is always turned off at Q ₂ In the period of action, Q ₁ And (4) always powering off.

In addition, T can be set because the air pollution is light in the energy-saving purification mode _ON ＜T _OFF . E.g. 2T _ON1 ＝T _OFF1 、2T _ON2 ＝T _OFF2 。

In the general purge mode, T may be set _ON ＝T _OFF I.e. T _ON1 ＝T _OFF1 、T _ON2 ＝T _OFF2 。

In some embodiments, two or more laser generators are provided in the laser purification apparatus 30, and different laser generators can be operated alternately.

Q ₁ Starting T _ON Back rotation to Q ₂ Turn on T _ON By analogy, up to Q _m Turn on T _ON Then returns to Q again ₁ And (6) circulating. When one laser generator is started, other laser generators are shut down.

This situation can be applied to the strong cleaning mode, where the laser generator is always on during the entire cleaning process.

Referring to fig. 17, in the strong purge mode, for example, with m =2, Q is ₁ Turn on T _ON1 Then, Q is turned off at the same time ₂ Opening; q ₂ Turn on T _ON2 Then, Q is turned off at the same time ₁ And (4) opening. Wherein T is _ON ＝T _OFF 。

In some embodiments, the laser decontamination device further comprises a human sensor for detecting the presence of a human; when people are detected to approach, the laser generator is controlled to be shut down, and the safety protection effect is achieved.

In some embodiments, referring to fig. 18-20, the air treatment device further comprises a high-voltage electrostatic source 40, the high-voltage electrostatic source 40 being electrically connected to the purge housing 31. The high voltage electrostatic source may specifically be a high voltage electrostatic generator.

High-voltage static electricity is exerted to purifying housing 31 by the high-voltage static electricity source, and high-voltage static electricity can make the inside of laser purification device 30 form the electric field, and when laser generator 32 during operation, can excite out air ion in laser purification device 30 is inside, and air ion can make the particulate matter in the air that flows through have an electric charge, and the microorganism suffers from the electric breakdown effect and is killed, and microorganism and dust easily attach to the inner wall under the electric field force effect to reach the effect of disinfecting and removing dust, improve the purification rate of air.

According to some embodiments of the present application, a conductive material is used for the exterior of the purge housing 31, and the high voltage electrostatic source 40 is electrically connected to the exterior of the purge housing 31.

Or the inner wall of the purifying shell 31 is made of conductive material, and the high-voltage static electricity source 40 is electrically connected with the inner wall of the purifying shell 31.

In some embodiments, the high-tension static source discharges positive high-tension static electricity, i.e., the purge housing 31 is charged with positive high-tension static electricity, which can be used to adsorb negatively charged particles.

Generally, when air is excited by external excitation to generate ions, the quantity of negative ions is greater than that of positive ions, and only negatively charged particles are adsorbed, so that a good purification effect can be achieved.

In some embodiments, the high voltage static electricity source discharges negative high voltage static electricity, i.e. the purifying housing 31 is charged with negative high voltage static electricity, and can be used for adsorbing positive ions in the air.

When the pollutants in the indoor air are small, the high-voltage electrostatic source is controlled to be started, and after the negative high-voltage electrostatic adsorbs positive ions, more negative ions can be reserved in the air, and the negative ions are beneficial to human health.

In some embodiments, the purge housing 31 may include a first housing portion 315, a second housing portion 316, and an intermediate housing portion 317. The intermediate shell portion 317 is disposed between the first and second shell portions 315 and 316, and the intermediate shell portion 317 is formed of an insulating material so that two electrical conductors, the first and second shell portions 315 and 316, can be separated.

The high voltage electrostatic source 40 includes a positive high voltage electrostatic source 41 and a negative high voltage electrostatic source 42. The positive high voltage electrostatic source 41 provides positive high voltage electrostatic, and the negative high voltage electrostatic source 42 provides negative high voltage electrostatic.

The positive high voltage electrostatic power source 41 is electrically connected to the first casing portion 315, and the negative high voltage electrostatic power source 42 is electrically connected to the second casing portion 316. That is, a part of the purifying housing 31 is charged with positive high-voltage static electricity, and a part of the purifying housing is charged with negative high-voltage static electricity, and can be used for adsorbing all the particles charged with positive electricity and negative electricity.

In some embodiments, the first casing portion 315 is electrically connected with the high voltage electrostatic source 40, and the second casing portion 316 is grounded. Wherein the high voltage static electricity source 40 provides positive high voltage static electricity, i.e. a part of the purifying housing 31 is electrified with positive high voltage static electricity, and a part is grounded. The positive high voltage is used for adsorbing particles charged with negative electricity, and simultaneously the positive high voltage repels the particles charged with positive electricity, so that the particles are adsorbed on one side of the ground, and the particles charged with positive electricity and the particles charged with negative electricity are purified simultaneously. Simultaneous adsorption of positively and negatively charged particles can be achieved using only one high voltage electrostatic source 40, reducing cost and simplifying design compared to the two high voltage electrostatic sources of the above embodiment.

In some embodiments, the first housing portion 315 is electrically connected to the high voltage electrostatic source 40 and the second housing portion 316 is grounded. Wherein the high voltage static electricity source 40 provides negative high voltage static electricity, i.e. a part of the purifying housing 31 is electrified with negative high voltage static electricity, and a part is grounded. The negative high voltage is used for adsorbing the particles charged with positive electricity, and meanwhile, the negative high voltage repels the particles charged with negative electricity, so that the particles are adsorbed on one side of the ground, and the particles charged with positive electricity and the particles charged with negative electricity are purified simultaneously. Simultaneous adsorption of positively and negatively charged particles can be achieved using only one high voltage electrostatic source 40, reducing cost and simplifying design compared to the two high voltage electrostatic sources of the above embodiment.

The first concept of the present application, owing to the laser purification device 30, utilizes the characteristics of the laser energy to sterilize fast to reach better purification effect and purification efficiency.

In the second concept of the present application, in the laser purification apparatus 30, since the inner wall of the purification casing 31 is set as a mirror surface, the radiation range of the laser in the purification air duct 313 can be increased by using the principle of mirror reflection, and it is ensured that the flowing air can be purified by the air.

The third design of this application, because the inner wall that purifies casing 31 is concave curved surface, laser can make reflection light concentrate more in purifying the wind channel after being reflected on concave curved surface, is favorable to improving laser purifying effect and purification efficiency.

In the fourth concept of the present application, since the inner wall of the purification casing 31 has the plurality of protrusions 314, when the laser beam is irradiated onto the protrusions 314, the diffuse reflection is easily formed, thereby increasing the light irradiation area and improving the purification rate.

According to the fifth concept of the present application, since the air guide blade 33 is disposed in the air purification duct, the air guide blade 33 blocks the air, so that the flow direction of the air in the air purification duct 313 is changed, the flow path of the air is extended, the flow time of the air in the air purification duct 313 is also extended, that is, the exposure time is increased, and the air purification rate is improved.

In the sixth concept of the present application, since the air guide blade 33 is disposed obliquely in the clean air duct 313, the air resistance to the air can be reduced by disposing the air guide blade in an oblique manner on the premise of extending the air flow path.

In the seventh concept of the present application, since the air guide blade 33 is arranged in a swinging manner, the requirements of both the purification rate and the wind resistance can be satisfied by changing the swinging angle of the air guide blade 33.

The eighth design of this application, because air guide vane 33 can swing the setting, can realize different purification rates through the swing angle that changes air guide vane 33, can correspond different purification mode to satisfy the purification demand of different environment, it is more intelligent.

According to the eighth concept of the present application, since the light barrier 37 is disposed at the air opening of the purification air duct, the laser leakage in the purification air duct can be blocked.

In the ninth concept of the present application, since the light barrier 37 is movable, when the laser generator 32 works, the light barrier 37 is in a shielding position to block the laser from leaking; when the laser generator is not operating, the light barrier 37 is in the open position, avoiding that it affects the wind speed.

The tenth idea of the present application is that since the laser generator 32 is intermittently turned on, the service life of the laser generator 32 can be prolonged, and the requirement of the whole machine application on the service life is satisfied.

The eleventh concept of the present application is that since the laser generator 32 is intermittently turned on, the heat dissipation of the laser generator is facilitated, the normal performance of the product is ensured, and the life of the laser generator is prolonged.

The twelfth concept of the present application can reduce power consumption and save energy because the laser generator 32 is intermittently turned on.

The thirteenth concept of the present application, because the high voltage static power source 40 is connected with the purification housing 31, the high voltage static makes the laser purification device 30 form an electric field therein, and the high voltage static adsorbs charged particles, thereby improving the purification rate of air.

Finally, it should be noted that: the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application.

The foregoing description, for purposes of explanation, has been presented in conjunction with specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the embodiments to the precise forms disclosed above. Many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles and the practical application, to thereby enable others skilled in the art to best utilize the embodiments and various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. An air treatment device, comprising: the laser purification device is used for purifying air; the laser purification device includes:

the air purifier comprises a purifying shell, a fan and a fan, wherein an air inlet and an air outlet and a purifying air channel communicated with the air inlet and the air outlet are formed in the purifying shell;

the laser generator is connected to the purification shell and emits laser into the purification air duct, and the laser is reflected for multiple times on the reflector surface layer so as to sterilize air in the purification air duct;

the air treatment device further comprises:

and the high-voltage static power source is electrically connected with the purification shell and provides high-voltage static electricity for the purification shell, so that an electric field is formed inside the purification shell to adsorb charged particles in the air.

2. The air treatment device of claim 1, wherein the purge housing includes a first housing portion, a second housing portion, and an intermediate housing portion connected between the first and second housing portions;

the material of the middle shell part is insulated;

the high-voltage static power source is electrically connected with the first shell part, and the second shell part is grounded.

3. The air treatment device of claim 1, wherein the purge housing includes a first housing portion, a second housing portion, and an intermediate housing portion connected between the first and second housing portions; the material of the middle shell part is insulated;

the high-voltage electrostatic source comprises a positive high-voltage electrostatic source and a negative high-voltage electrostatic source; the positive high-voltage electrostatic source is electrically connected with the first shell part, and the negative high-voltage electrostatic source is electrically connected with the second shell part.

4. The air treatment device of claim 1, wherein the exterior of the decontamination housing is made of an electrically conductive material, and the high voltage electrostatic source is electrically connected to the exterior of the decontamination housing.

5. The air treatment device of claim 1, wherein the inner wall of the purification housing is made of conductive material, and the high-voltage static electricity source is electrically connected with the inner wall of the purification housing.

6. The air treatment device according to claim 1, wherein the high-voltage static electricity source emits positive high-voltage static electricity or negative high-voltage static electricity.

7. The air treatment device of claim 1, wherein the reflector layer is an aluminum or tin foil.

8. The air treatment device of claim 1, wherein the reflector layer is a metal or glass.

9. The air treatment device of claim 1, wherein the reflector layer is integrally formed with the purge housing.

10. The air treatment device of claim 1, wherein the laser light generated by the laser generator impinges the mirror layer in an oblique manner when the mirror layer is planar.

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