CN114001431B - Active fog ion generator for indoor environment disinfection - Google Patents

Abstract

An active fog ion generator for indoor environment disinfection relates to the technical field of air disinfection. The active fog ion generator comprises a shell, an active fog ion generating assembly fixedly arranged in the shell, an air cooling assembly arranged on the side surface of the active fog ion generating assembly and a heating assembly used for heating the active fog ions emitted by the active fog ion generating assembly, wherein the active fog ion generating assembly generates low-temperature air to flow to the air cooling assembly, the active fog ions generated by the active fog ion generating assembly flow to the heating assembly, the air cooling assembly cools the active fog ion generating assembly, and hot air formed during cooling flows to the heating assembly to heat the active fog ions; the invention guides the low-temperature air generated by the low-temperature environment manufactured by the refrigerating piece to the heating end of the refrigerating piece to radiate the refrigerating piece, thereby being convenient for fully utilizing the low-temperature air, saving energy, greatly improving the radiating efficiency of the heating end of the refrigerating piece and enhancing the refrigerating effect of the refrigerating end of the refrigerating piece.

Description

Active fog ion generator for indoor environment disinfection

Technical Field

The invention belongs to the technical field of air sterilization, and particularly relates to an active fog ion generator for indoor environment sterilization.

Background

The air active fog ions have the functions of purifying air and killing viruses and bacteria. In the air, active fog ions are electronegative and attract positive and negative of floating dust (PM 2.5), aerosol and other substances with electropositive property, and are combined with each other to rapidly settle so as to avoid the aggregation in the air, thereby cutting off the infection path of the new coronavirus, and greatly reducing the probability of virus infection; on the other hand, the small-particle-size active fog ions can change the internal and external potentials of the virus capsid or reverse the polarities of the internal and external potentials, so that the virus capsid can be directly killed.

Active fog ions generated by the existing active fog ion generator are generally naturally discharged, the active fog ion disinfection is generally used indoors, the indoor general air circulation is poor, the diffusion rate of the active fog ions discharged from the device is low, the disinfection effect of the active fog ion generator is poor, meanwhile, the active fog ion generator generally needs to liquefy water vapor in the air and ionize the liquefied water to generate the active fog ions, the low-temperature environment needs to be manufactured by the water vapor liquefaction, and the low-temperature environment is generally manufactured by using a refrigerating sheet. The refrigeration piece has cold junction and hot junction, and the heat dissipation of hot junction is faster, and the refrigeration effect of cold junction is better, therefore we need carry out the heat dissipation to the refrigeration piece hot junction and handle to this makes its cold junction possess good refrigeration effect, and the refrigeration piece hot junction uses radiator fan to produce the air current to dispel the heat usually, and the air current is normal atmospheric temperature state, and the radiating effect is not good.

Therefore, the existing active fog ion generator has the problems of poor killing effect caused by low diffusion rate of active fog ions and poor heat dissipation effect of the cooling fin caused by the cooling fan when the cooling fin is used for cooling. To this end, we propose an active mist ionizer for indoor environment disinfection.

Disclosure of Invention

The invention aims to provide an active fog ion generator for indoor environment sterilization, which can effectively solve the problems of poor sterilization effect caused by low diffusion rate of active fog ions and poor heat dissipation effect of a cooling fan on a cooling plate when the cooling plate is used for cooling in the conventional active fog ion generator in the background art.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention provides an active fog ion generator for indoor environment disinfection, which comprises a shell, an active fog ion generating assembly fixedly arranged in the shell, an air cooling assembly arranged on the side surface of the active fog ion generating assembly and a heating assembly for heating active fog ions emitted by the active fog ion generating assembly, wherein the active fog ion generating assembly generates low-temperature air to flow to the air cooling assembly;

the active fog ion generating assembly comprises a refrigerating sheet arranged below the inner part of the shell, and the air cooling assembly dissipates heat from the bottom of the refrigerating sheet; the refrigeration end of the refrigeration piece generates a low-temperature environment, so that water vapor in the air is liquefied, and the active mist ion generating assembly generates active mist ions through the liquefied water. Wherein, the air can lower the temperature equally when the low temperature environment that the refrigeration end of refrigeration piece produced, through the end that generates heat with low temperature air direction refrigeration piece dispels the heat to the refrigeration piece, is convenient for make cold air can fully utilized to improved the radiating efficiency of the end that generates heat of refrigeration piece greatly, strengthened the refrigeration effect of the refrigeration end of refrigeration piece simultaneously, make the active fog ion of device produce the effect better.

The air cooling assembly comprises a first air duct fixedly arranged on the air outlet side of the active fog ion generating assembly, a heat exchange block fixedly arranged at the bottom of the refrigerating sheet, a second air duct fixedly arranged at the air outlet end of the heat exchange block, and a first fan fixedly arranged in the second air duct, the air outlet end of the first air duct is fixedly connected with the air inlet end of the heat exchange block, a first heat exchange chamber for air circulation is arranged in the heat exchange block, and the first heat exchange chamber is of an S-shaped structure; the opening sectional area that first air duct gave vent to anger the end is less than the opening sectional area of inlet end, the inlet end cross-section of the S type structure of first heat transfer chamber is the same with the opening sectional area of first air duct inlet end simultaneously, through reducing the sectional area, be convenient for improve gaseous flow rate that gets into first heat transfer indoor portion, avoid the problem that the heat that the heated air flow slowly leads to accumulates, be convenient for simultaneously improve the contact time and the area of contact of air and heat transfer piece, so that heat exchange efficiency improves greatly, make the heated air effect of being heated better, make the heated air follow-up better to active fog ion heating effect. The first fan facilitates creating an air flow.

The heating assembly comprises a heat insulation pipe fixedly arranged in the middle of the inside of the shell and a heat conduction pipe arranged in the heat insulation pipe, a second heat exchange chamber is arranged in the heat insulation pipe, the heat conduction pipe is fixedly arranged in the middle of the inside of the second heat exchange chamber, the shape of the heat conduction pipe is matched with the second heat exchange chamber and is of a spiral structure, active fog ions generated by the active fog ion generation assembly flow into the heat conduction pipe, and the air outlet end of the second air guide pipe is communicated with the inside of the second heat exchange chamber. The heat insulation pipe is strong in heat insulation performance, and hot air enters the heat insulation pipe and heats the heat conduction pipe after entering the second heat exchange chamber, so that active fog ions in the heat conduction pipe are heated, the motion rate of the active fog ions is increased, the diffusion efficiency of the active fog ions after the discharging device is greatly increased, and the sterilizing effect of the device is enhanced. In the invention, the heat conduction pipe is positioned in the second heat exchange chamber, and heat transfer is carried out from high temperature to low temperature, so that heat transfer cannot occur outwards after the active fog ions are heated, the heat loss in the heating of the active fog ions is reduced conveniently, the energy generated in the device is fully utilized by the design, and the active fog ion generation efficiency and the killing capacity of the device are greatly improved.

Preferably, the active fog ion generating assembly further comprises a first electrode plate fixedly mounted above the refrigerating plate, support columns fixedly mounted at four corner ends of the first electrode plate, a second electrode plate fixedly mounted above the support columns, two heat insulation plates fixedly mounted on the side faces of the support columns, and a circuit board fixedly mounted on the side face of one of the heat insulation plates, the two heat insulation plates are located on opposite sides of the whole active fog ion generating assembly, the second electrode plate is over against the first electrode plate, and a hole for flowing out of active fog ions is formed in the middle of the second electrode plate. The heat shield is convenient for guarantee the low temperature environment between first electrode slice and the second electrode slice.

The second electrode sheet and the first electrode sheet are loaded with a high voltage of sufficient strength to break down air between the second electrode sheet and the first electrode sheet. The second electrode slice is the positive pole, and first electrode slice is the negative pole, and the refrigeration piece makes the comdenstion water in the air condense on first electrode slice through giving first electrode slice cooling, and the comdenstion water on the first electrode slice can be punctureed simultaneously when high-tension electricity punctures first electrode slice and second electrode slice, generates active fog particle, active fog ion promptly, and the active fog ion that generates moves to second electrode slice direction along first electrode slice to distribute away through the hole on the second electrode slice.

Preferably, the lower end of the housing is provided with an air inlet assembly, the air inlet assembly comprises an air gathering ring pipe and an air inlet pipe which are fixedly mounted at the lower end inside the housing, the bottom of the housing is provided with an air hole communicated with the inside of the air gathering ring pipe, one end of the air inlet pipe is fixedly connected to the air outlet end of the air gathering ring pipe, the other end of the air inlet pipe is fixedly connected with the air inlet end of the active mist ion generating assembly, the end part of the air inlet pipe and the heat insulating sheet are located on the adjacent sides of the whole active mist ion generating assembly, and the first air guide pipe and the air inlet pipe are located on the opposite sides of the whole active mist ion generating assembly. The gas collecting ring pipe and the gas inlet pipe are convenient for collecting the air at the lower end of the shell, the lower end of the shell is close to the ground, the ground evaporation capacity is larger, the humidity is higher, the water vapor content in the air is higher, and more moisture can be generated after liquefaction.

Preferably, the heat conductive pipe has a spiral blade structure. Helical blade structure makes active fog ion and heat pipe inner wall distance shorter for active fog ion is heated sooner, and the efficiency of being heated is higher, and the effect of being heated is higher.

Preferably, a second fan is fixedly mounted above the second electrode plate, and an air outlet end of the second fan is fixedly connected to an air inlet end of the heat conduction pipe. The second fan is convenient for with the inside of the leading-in heat pipe of active fog ion, avoids the air to receive first fan influence to get into first electrode slice and second electrode slice from the hole simultaneously and leads to blowing back active fog ion.

Preferably, the T-shaped pipe is fixedly mounted at the air outlet end of the heat conducting pipe, the air outlet block is fixedly mounted on the side surface of the shell, the inside of the air outlet block is separated into an upper air outlet chamber and a lower air outlet chamber through a baffle, the T-shaped pipe is communicated with the lower air outlet chamber of the air outlet block, and an air outlet is formed in the upper portion of the inside of the air outlet block and on one side, far away from the T-shaped pipe, of the air outlet block. The T-tube and the air outlet block are configured to facilitate the discharge of active mist ions from opposite sides of the device as a whole.

Preferably, an air outlet pipe is fixedly mounted above the heat insulation pipe, an air inlet end of the air outlet pipe is communicated with an air outlet end of the second heat exchange chamber, and an air outlet end of the air outlet pipe is communicated with the upper air outlet chamber. Go out the active fog ion that air chamber discharge was heated down, go up air-heating in the air chamber eduction gear, according to the rising principle of hot air, hot air is located the active fog ion's of being heated top, the hot air rises the in-process and the top air mixing of active fog ion, make the top air of active fog ion higher than normal air temperature, be convenient for slow down the cooling rate of active fog ion, make active fog ion outwards diffuse with higher temperature in a longer time, be convenient for further improve active fog ion diffusion efficiency.

Preferably, a power supply is fixedly mounted at the top of the inner cavity of the shell. The power supply is convenient for supplying power to the whole device.

Preferably, a movable base is fixedly mounted at the bottom of the housing. The movable base is convenient for the drive device to integrally move, adopts the existing principle, and belongs to the known technology.

Preferably, an adjusting panel is fixedly mounted above the housing. The adjusting panel is convenient for parameter setting of the device and display of corresponding data.

The invention has the following beneficial effects:

1. the invention guides the low-temperature air generated in the low-temperature environment manufactured by the refrigerating piece to the heating end of the refrigerating piece to radiate the refrigerating piece, so that the low-temperature air can be fully utilized, the energy is saved, the heat radiation is carried out through the low-temperature air, the heat radiation efficiency of the heating end of the refrigerating piece is greatly improved, the refrigerating effect of the refrigerating end of the refrigerating piece is enhanced, and the active fog ion generating effect of the device is better.

2. According to the invention, the problem of heat accumulation caused by slow flowing of heated air is avoided by improving the flow velocity of low-temperature air in the heat exchange block, and the design of the S-shaped structure of the first heat exchange chamber in the heat exchange block is convenient for improving the contact time and the contact area of the air and the heat exchange block, so that the heat exchange efficiency is greatly improved, the heated air is better in heating effect, and the subsequent heated air has better heating effect on active fog ions.

3. According to the invention, hot air enters the second heat exchange chamber in the heat insulation pipe and then heats the heat conduction pipe, so that active fog ions in the heat conduction pipe are heated, the moving speed of the active fog ions is increased, the diffusion efficiency of the active fog ions after being discharged out of the device can be greatly improved, and the sterilizing effect of the device is enhanced. And because the heat pipe is located the second heat transfer indoor, because the heat transfer is by high temperature to low temperature transmission, consequently the outside heat transfer that produces can not be carried out to active fog ion after being heated, be convenient for make the heat waste in the active fog ion heating reduce, carry out the heating of active fog ion through the air that is heated in this design for the energy that produces in the make full use of device, improved the active fog ion movement rate of device greatly, so that the killing ability reinforcing.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a front cross-sectional view of an active mist ionizer for indoor environment sterilization according to the present invention;

FIG. 2 is a perspective view of the overall structure of the active mist ion generator for indoor environment disinfection provided by the present invention;

FIG. 3 is a perspective view of an active mist ion generator for indoor environmental decontamination according to the present invention;

FIG. 4 is an enlarged view of part A of FIG. 1 of the active mist ionizer for indoor environment sterilization according to the present invention;

FIG. 5 is an enlarged view of a portion B of FIG. 1 of the active mist ionizer for indoor environment sterilization according to the present invention;

FIG. 6 is a perspective view of an active mist ionizer heating assembly for indoor environment decontamination in accordance with the present invention;

FIG. 7 is a perspective view of a heat pipe of an active mist ion generator for indoor environment disinfection provided by the present invention;

FIG. 8 is a plan cross-sectional view of an active mist ionizer heating assembly for indoor environment decontamination in accordance with the present invention;

FIG. 9 is a perspective view of a heat exchange block of the active mist ionizer for indoor environment sterilization in accordance with the present invention;

fig. 10 is a plan sectional view of a heat exchange block of an active mist ionizer for indoor environment sterilization provided in accordance with the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a housing; 2. an active mist ion generating assembly; 21. a refrigeration plate; 22. a first electrode sheet; 23. a support pillar; 24. a second electrode sheet; 25. a heat insulating sheet; 26. a circuit board; 3. an air-cooled assembly; 31. a first air duct; 32. a heat exchange block; 33. a second air duct; 34. a first fan; 4. a heating assembly; 41. a heat insulating pipe; 42. a heat conducting pipe; 5. a first heat exchange chamber; 6. a second heat exchange chamber; 7. a hole; 8. a gas collecting ring pipe; 9. an air inlet pipe; 10. air holes; 11. a second fan; 12. a T-shaped pipe; 13. gas outlet block; 14. an exhaust port; 15. an air outlet pipe; 16. a power source; 17. moving the base; 18. and adjusting the panel.

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.

In the description of the present invention, it is to be understood that the terms "upper", "middle", "outer", "inner", and the like, indicate orientations or positional relationships, are used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referenced components or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example (b):

FIG. 1 is a front cross-sectional view of an active mist ionizer according to the present invention for indoor environment sterilization; fig. 2 is a perspective view of an overall structure of an active mist ion generator for indoor environment sterilization according to the present invention, and please refer to fig. 1-2, the active mist ion generator for indoor environment sterilization according to the present invention includes a housing 1, an active mist ion generating assembly 2 fixedly installed inside the housing 1, an air cooling assembly 3 disposed at a side of the active mist ion generating assembly 2, and a heating assembly 4 for heating the active mist ions generated by the active mist ion generating assembly 2, wherein the active mist ion generating assembly 2 generates low temperature air and flows to the air cooling assembly 3, the active mist ions generated by the active mist ion generating assembly 2 flow to the heating assembly 4, the air cooling assembly 3 cools the active mist ion generating assembly 2, and the hot air formed during cooling flows to the heating assembly 4 to heat the active mist ions.

Fig. 3 is a perspective view of an active mist ion generating assembly of an active mist ion generator for indoor environment sterilization according to the present invention, please refer to fig. 1 and 3, wherein the active mist ion generating assembly 2 includes a refrigerating sheet 21 disposed below the inside of the housing 1, and the air cooling assembly 3 dissipates heat from the bottom of the refrigerating sheet 21; the refrigeration end of the refrigeration piece 21 generates a low-temperature environment, so that water vapor in the air is liquefied, and the active mist ion generating assembly 2 generates active mist ions through the liquefied water. Wherein, the air can lower the temperature equally when the low temperature environment that the refrigeration end of refrigeration piece 21 produced, end through generating heat with low temperature air direction refrigeration piece 21 dispels the heat to refrigeration piece 21, be convenient for make low temperature air can fully utilized, and save the energy, dispel the heat through low temperature air, the radiating efficiency in the heating end of refrigeration piece 21 has been improved greatly, the refrigeration effect of the refrigeration end of refrigeration piece 21 has been strengthened simultaneously, make the active fog ion emergence rate of device better.

FIG. 5 is an enlarged view of a portion B of FIG. 1 of the active mist ionizer for indoor environment sterilization according to the present invention; FIG. 9 is a perspective view of a heat exchange block of the active mist ionizer for indoor environment sterilization in accordance with the present invention; fig. 10 is a plan sectional view of an active mist ion generator heat exchange block for indoor environment sterilization provided by the present invention, please refer to fig. 1, fig. 5, fig. 9 and fig. 10, wherein an air cooling assembly 3 includes a first air duct 31 fixedly installed at an air outlet side of an active mist ion generating assembly 2, a heat exchange block 32 fixedly installed at a bottom of a cooling fin 21, a second air duct 33 fixedly installed at an air outlet end of the heat exchange block 32, and a first fan 34 fixedly installed inside the second air duct 33, the air outlet end of the first air duct 31 is fixedly connected with an air inlet end of the heat exchange block 32, a first heat exchange chamber 5 for air circulation is opened inside the heat exchange block 32, and the first heat exchange chamber 5 is of an S-shaped structure; first air duct 31 gives vent to anger the opening sectional area of end and is less than the opening sectional area of inlet end, the inlet end cross-section of the S type structure of first heat transfer chamber 5 is the same with the opening cross-section of first air duct 31 inlet end simultaneously, through reducing the sectional area, be convenient for improve the gaseous velocity of flow that gets into first heat transfer chamber 5 inside, the problem of the heat that the heated air flow slowly leads to deposits has been avoided, be convenient for simultaneously improve the contact time and the area of contact of air and heat transfer piece 32, so that heat exchange efficiency improves greatly, make the heated air effect of being heated better, make the heated air follow-up better to active fog ion heating effect. The first fan 34 facilitates creating an air flow.

FIG. 6 is a perspective view of an active mist ionizer heating assembly for indoor environment decontamination in accordance with the present invention; FIG. 7 is a perspective view of a heat pipe of an active mist ion generator for indoor environment disinfection provided by the present invention; fig. 8 is a plan sectional view of an active mist ion generator heating assembly for indoor environment sterilization according to the present invention, referring to fig. 1 and fig. 6-8, a heating assembly 4 includes a heat insulation pipe 41 fixedly installed in the middle of the inside of a housing 1, and a heat conduction pipe 42 disposed inside the heat insulation pipe 41, a second heat exchange chamber 6 is disposed inside the heat insulation pipe 41, the heat conduction pipe 42 is fixedly disposed in the middle of the inside of the second heat exchange chamber 6, the shape of the heat conduction pipe 42 matches the shape of the second heat exchange chamber 6, and is a spiral structure, active mist ions generated by an active mist ion generating assembly 2 flow into the heat conduction pipe 42, and the air outlet end of a second air guide pipe 33 is communicated with the inside of the second heat exchange chamber 6. The heat insulation pipe 41 has strong heat insulation performance, and hot air enters the heat insulation pipe 41 and heats the heat conduction pipe 42 after entering the second heat exchange chamber 6, so that active mist ions in the heat conduction pipe 42 are heated, the movement rate of the active mist ions is increased, the diffusion efficiency of the active mist ions after the discharging device is greatly increased, and the sterilizing effect of the device is enhanced. Because the heat pipe 42 is located in the second heat exchange chamber 6 in the design, because the heat transfer is from high temperature to low temperature transfer, the active fog ions can not generate heat transfer outwards after being heated, the heat loss in the active fog ion heating is convenient to reduce, the active fog ions are heated through heated air in the design, the energy generated in the device is fully utilized, the active fog ion movement rate of the device is greatly improved, and the killing capability is enhanced.

Still as shown in fig. 3, the active fog ion generating assembly 2 further includes a first electrode plate 22 fixedly installed above the refrigerating plate 21, support columns 23 fixedly installed at four corner ends of the first electrode plate 22, a second electrode plate 24 fixedly installed above the support columns 23, two heat insulating plates 25 fixedly installed on the side surfaces of the support columns 23, and a circuit board 26 fixedly installed on the side surface of one of the heat insulating plates 25, wherein the two heat insulating plates 25 are located on opposite sides of the whole active fog ion generating assembly 2, the second electrode plate 24 is over against the first electrode plate 22, and a hole 7 for flowing out of active fog ions is formed in the middle of the second electrode plate 24. The heat insulating sheet 25 facilitates securing a low temperature environment between the first electrode sheet 22 and the second electrode sheet 24.

In the above configuration, a high voltage is applied across second electrode sheet 24 and first electrode sheet 22, with a voltage level sufficient to break through the air between second electrode sheet 24 and first electrode sheet 22. Second electrode sheet 24 is the positive pole, and first electrode sheet 22 is the negative pole, and refrigeration piece 21 makes the comdenstion water in the air condense on first electrode sheet 22 through giving first electrode sheet 22 cooling, and the comdenstion water on first electrode sheet 22 can be punctured simultaneously when high-tension electricity punctures first electrode sheet 22 and second electrode sheet 24, generates active fog particle, active fog ion promptly, and the active fog ion that generates moves to second electrode sheet 24 direction along first electrode sheet 22 to distribute away through hole 7 of second electrode sheet 24.

Fig. 4 is an enlarged view of a portion a in fig. 1 of the active mist ion generator for indoor environment sterilization according to the present invention, please refer to fig. 1 and 4, an air inlet assembly is disposed at a lower end of a housing 1, the air inlet assembly includes an air collecting loop 8 and an air inlet pipe 9 fixedly mounted at a lower end inside the housing 1, an air hole 10 communicated with the inside of the air collecting loop 8 is disposed at a bottom of the housing 1, one end of the air inlet pipe 9 is fixedly connected to an air outlet end of the air collecting loop 8, the other end of the air inlet pipe 9 is fixedly connected to an air inlet end of the active mist ion generating assembly 2, an end of the air inlet pipe 9 and a heat insulation sheet 25 are located at adjacent sides of the whole active mist ion generating assembly 2, and a first air guide pipe 31 and the air inlet pipe 9 are located at opposite sides of the whole active mist ion generating assembly 2. Gather the lower extreme air of gas ring pipe 8 and intake pipe 9 and be convenient for gather casing 1, the lower extreme of casing 1 is for being close to ground department, and ground evaporation capacity is bigger, and humidity is higher, and vapor content in the air is higher, is convenient for produce more moisture after the liquefaction.

As also shown in fig. 7 and 8, the heat conductive pipes 42 have a spiral blade structure. The helical blade structure makes active fog ion and heat pipe 42 inner wall distance shorter for active fog ion is heated faster, and the efficiency of being heated is higher, and the effect of being heated is higher.

As shown in fig. 1, a second fan 11 is fixedly mounted above the second electrode sheet 24, and an outlet end of the second fan 11 is fixedly connected to an inlet end of the heat pipe 42. The second fan 11 facilitates the introduction of active mist ions into the interior of the heat pipe 42 while avoiding air from being affected by the first fan 34 from entering the first and second electrode sheets 22 and 24 from the aperture 7 and causing the active mist ions to be blown back.

Still as shown in fig. 1, the T-shaped pipe 12 is fixedly mounted at the outlet end of the heat conducting pipe 42, the air outlet block 13 is fixedly mounted at the side surface of the housing 1, the inside of the air outlet block 13 is partitioned into an upper air outlet chamber and a lower air outlet chamber by a baffle, the T-shaped pipe 12 is communicated with the lower air outlet chamber of the air outlet block 13, and an air outlet 14 is formed at the upper side of the inside of the air outlet block 13, which is far away from the side of the T-shaped pipe 12. The T-tube 12 and the air outlet block 13 are configured to facilitate the discharge of active mist ions from opposite sides of the device as a whole.

Still as shown in fig. 1, an air outlet pipe 15 is fixedly installed above the heat insulation pipe 41, an air inlet end of the air outlet pipe 15 is communicated with an air outlet end of the second heat exchange chamber 6, and an air outlet end of the air outlet pipe 15 is communicated with the upper air outlet chamber. Go out the active fog ion that air chamber discharge was heated down, go up air-heating in the air chamber eduction gear, according to the rising principle of hot air, hot air is located the active fog ion's of being heated top, the hot air rises the in-process and the top air mixing of active fog ion, make the top air of active fog ion higher than normal air temperature, be convenient for slow down the cooling rate of active fog ion, make active fog ion outwards diffuse with higher temperature in a longer time, be convenient for further improve active fog ion diffusion efficiency.

As also shown in fig. 1 and 2, a power supply 16 is fixedly mounted on the top of the inner cavity of the housing 1. The power supply 16 facilitates the powering of the device as a whole. The bottom of the housing 1 is fixedly provided with a movable base 17. The movable base 17 is convenient for the whole driving device to move, and the movable base 17 belongs to the known technology and adopts the existing principle. An adjusting panel 18 is fixedly mounted above the housing 1. The adjustment panel 18 facilitates the setting of parameters of the device and the display of corresponding data.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, 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 of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. An active fog ion generator for indoor environment disinfection, characterized in that: the active fog ion generator comprises a shell (1), an active fog ion generating assembly (2) fixedly installed in the shell (1), an air cooling assembly (3) arranged on the side face of the active fog ion generating assembly (2) and a heating assembly (4) used for heating active fog ions emitted by the active fog ion generating assembly (2), wherein the active fog ion generating assembly (2) generates low-temperature air to flow to the air cooling assembly (3), the active fog ions generated by the active fog ion generating assembly (2) flow to the heating assembly (4), the air cooling assembly (3) cools the active fog ion generating assembly (2), and hot air formed during cooling flows to the heating assembly (4) to heat the active fog ions;

the active fog ion generating assembly (2) comprises a refrigerating sheet (21) arranged below the inner part of the shell (1); the air cooling assembly (3) comprises a first air duct (31) fixedly mounted on the air outlet side of the active fog ion generating assembly (2), a heat exchange block (32) fixedly mounted at the bottom of the refrigerating sheet (21), a second air duct (33) fixedly mounted at the air outlet end of the heat exchange block (32), and a first fan (34) fixedly mounted inside the second air duct (33), the first air duct (31) is communicated with the heat exchange block (32), a first heat exchange chamber (5) is formed inside the heat exchange block (32), and the first heat exchange chamber (5) is of an S-shaped structure; heating element (4) including fixed mounting at the inside middle heat insulating tube (41) of casing (1), set up heat pipe (42) at heat insulating tube (41), second heat transfer room (6) have been seted up to the inside of heat insulating tube (41), heat pipe (42) are located the inside of second heat transfer room (6), and are helical structure with second heat transfer room (6), active fog ion that active fog ion produced subassembly (2) flows into inside heat pipe (42), second air duct (33) and second heat transfer room (6) intercommunication.

2. The active mist ionizer of claim 1 for indoor environment sanitization, wherein: the active fog ion generation assembly (2) further comprises a first electrode plate (22) fixedly mounted above the refrigerating plate (21), support columns (23) fixedly mounted at four corner ends of the first electrode plate (22), a second electrode plate (24) fixedly mounted above the support columns (23), two heat insulation plates (25) fixedly mounted on the side faces of the support columns (23) and a circuit board (26) fixedly mounted on the side face of one of the heat insulation plates (25), the two heat insulation plates (25) are located on the opposite sides of the whole active fog ion generation assembly (2), the second electrode plate (24) is just opposite to the top of the first electrode plate (22), and a hole (7) for flowing out of active fog ions is formed in the middle of the second electrode plate (24).

3. An active mist ionizer for indoor environment disinfection according to claim 2, characterized in that: the lower extreme of casing (1) is provided with the subassembly that admits air, the subassembly that admits air includes that fixed mounting gathers gas ring pipe (8) and intake pipe (9) at the inside lower extreme of casing (1), the bottom of casing (1) is seted up and is gathered gas pocket (10) of the inside intercommunication of gas ring pipe (8), the one end fixed connection of intake pipe (9) is gathered the end of giving vent to anger of gas ring pipe (8), the other end of intake pipe (9) and the inlet end fixed connection of active fog ion generation subassembly (2), the tip and heat insulating sheeting (25) of intake pipe (9) are located the holistic adjacent side of active fog ion generation subassembly (2), first air duct (31) and intake pipe (9) are located the holistic opposite side of active fog ion generation subassembly (2).

4. An active mist ionizer for indoor environment disinfection according to claim 3, characterized in that: the heat conduction pipe (42) is of a spiral blade structure.

5. The active mist ionizer of claim 4 for indoor environment sanitization, wherein: and a second fan (11) is fixedly mounted above the second electrode plate (24), and the air outlet end of the second fan (11) is fixedly connected with the air inlet end of the heat conduction pipe (42).

6. The active mist ionizer of claim 5 for indoor environment sanitization, wherein: the heat pipe is characterized in that a T-shaped pipe (12) is fixedly mounted at the air outlet end of the heat conducting pipe (42), an air outlet block (13) is fixedly mounted on the side face of the shell (1), an upper air outlet chamber and a lower air outlet chamber are separated from the inside of the air outlet block (13) through a baffle, the T-shaped pipe (12) is communicated with the lower air outlet chamber of the air outlet block (13), and an air outlet (14) is formed in one side, away from the T-shaped pipe (12), of the air outlet block (13).

7. The active mist ionizer of claim 6 for indoor environment sanitization, wherein: an air outlet pipe (15) is fixedly mounted above the heat insulation pipe (41), the air inlet end of the air outlet pipe (15) is communicated with the air outlet end of the second heat exchange chamber (6), and the air outlet end of the air outlet pipe (15) is communicated with the upper air outlet chamber.

8. The active mist ionizer of claim 7 for indoor environment sanitization, wherein: and a power supply (16) is fixedly arranged at the top of the inner cavity of the shell (1).

9. The active mist ionizer of claim 8 for indoor environment sanitization, wherein: the bottom of the shell (1) is fixedly provided with a movable base (17).

10. An active mist ionizer for indoor environment disinfection according to any one of claims 1-9, characterized in that: an adjusting panel (18) is fixedly arranged above the shell (1).

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