CN114060989B - Atomization module for fresh air system and atomization method thereof - Google Patents

Abstract

The invention discloses an atomization module for a fresh air system and an atomization method thereof, wherein the atomization module for the fresh air system comprises: micropore atomizer, a plurality of micropore atomizer arrays are installed in the interior space, communicate through a plurality of liquid pipeline between a plurality of micropore atomizers, be equipped with intelligent induction system in the interior space, central authorities 'fluid infusion system and intelligent humidification control system, intelligent humidification control system respectively with intelligent induction system, central authorities' fluid infusion system electricity is connected, intelligent humidification control system is according to the atomization effect of the environmental information automatically regulated intelligent regulation atomizer that the sensor gathered, and then realize that the new trend system guarantees indoor constant humidity and clean purpose all the time under energy-conserving circumstances.

Description

Atomization module for fresh air system and atomization method thereof

Technical Field

The invention relates to the technical field of atomization humidifiers, in particular to an atomization module for a fresh air system and an atomization method thereof.

Background

Along with the development of economy and the improvement of the living standard of people, the requirements of people on the quality of life and health are higher and higher, the humidification is just needed, the humidification quantity of the humidifier on the market is within the range of 300-500mL/h at present, the humidifier can only meet the use in the environment below 100 cubic meters, the product for the large space humidification requirement exceeding 100 cubic meters is extremely small, however, the large space humidification has large fog output quantity, if the large fog humidification is carried out on one point in a centralized mode, a large humidity difference can be generated due to the distance, the indoor constant humidity cannot be automatically adjusted according to the requirement, in order to solve the use pain point, the atomization effect of the large space integral intelligent humidification and intelligent adjustment atomizer is realized, and the purpose of ensuring indoor constant humidity and cleanness all the time under the condition of realizing energy conservation of a fresh air system is particularly important.

Disclosure of Invention

The invention aims to provide an atomization module for a fresh air system and an atomization method thereof, which are used for solving the problems in the background art that: the required mist quantity is large when large space humidification is carried out, and if the large-mist-quantity humidification is carried out by concentrating on one point, the problem of large humidity difference is caused by the distance.

In order to achieve the purpose, the invention discloses an atomization module for a fresh air system and an atomization method thereof, wherein the atomization module comprises: micropore atomizer, it is a plurality of micropore atomizer array installs in the interior space, and is a plurality of through a plurality of liquid pipeline intercommunication between the micropore atomizer, be equipped with intelligent induction system, central fluid infusion system and intelligent humidification control system in the interior space, intelligent humidification control system is connected with intelligent induction system, central fluid infusion system electricity respectively.

Preferably, a plurality of micropore atomizers and a plurality of liquid pipeline one set up on the wall body of indoor space optional position, two one ends of liquid pipeline run through the wall body of indoor space with the one end of a plurality of micropore atomizers is connected, central authorities' fluid infusion system passes through two other ends of liquid pipeline with the other end intercommunication of a plurality of micropore atomizers.

Preferably, the micro-porous atomizer comprises: the atomizing device comprises an installation base, wherein a plurality of installation holes are formed in the upper end face of the installation base, and a plurality of atomizing modules are installed in one-to-one correspondence with the installation holes.

Preferably, the smart sensor device includes: the intelligent humidification control system comprises a temperature and humidity detection module, a human body induction module and an air monitoring module, wherein the temperature and humidity detection module, the human body induction module and the air monitoring module are respectively electrically connected with the intelligent humidification control system.

Preferably, the installation mode of the atomization module and the installation hole is as follows: any one of screw thread, rotary buckle, push-pull, magnetic attraction and press buckle.

Preferably, the installation base is connected with the control module group, the control module group is connected with intelligent humidification control system electricity, the control module group includes: the lower shell is fixedly connected with the upper shell, a first pipe orifice is arranged at the front end of the lower shell, a through hole and a second pipe orifice are arranged at the right end of the lower shell, and a wire plug penetrates through the through hole;

be equipped with in the cavity that lower casing and last casing formed: the three-way valve, the pressure reducing valve, the throttle valve, the electromagnetic valve and the control panel;

the right end of the three-way valve is connected with a first connecting pipeline through a second pipe orifice, the left end of the three-way valve is connected with the right end of the pressure reducing valve through a second connecting pipeline, and the lower end of the three-way valve is connected with one end of the electromagnetic valve through a first elbow;

the left end of the pressure reducing valve is connected with a municipal water supply pipeline;

the other end of the electromagnetic valve is connected with one end of the throttle valve through a second elbow;

one end of a connecting pipeline III penetrates through the pipe orifice I to be connected with the other end of the throttling valve, and the other end of the connecting pipeline III is connected with the atomizing module;

one end of the control panel is electrically connected with the wire plug, and the other end of the control panel is electrically connected with the atomization module through a wire.

Preferably, the atomization module comprises:

the liquid storage device comprises a shell, a liquid storage cavity and a plurality of atomizer working areas, wherein the liquid storage cavity and the atomizer working areas are arranged in the shell, a liquid inlet channel is formed in the upper surface of the shell, liquid enters the liquid storage cavity from the liquid inlet channel, the liquid is provided for the atomizer working areas through the liquid storage cavity, and the liquid inlet channel is connected with a third connecting pipeline;

a plurality of atomizers are integrated at the bottom of the shell, an atomizer working area is arranged on the inner bottom surface of the shell, one part of the atomizers is arranged at the outer side of the bottom of the shell, and the other part of the atomizers is arranged in the atomizer working area;

a flow divider is arranged in the liquid storage cavity, an installation groove is formed in the inner top surface of the liquid storage cavity, the top end of the flow divider is fixedly connected in the installation groove, and the top of the installation groove is communicated with the liquid inlet channel;

the flow divider is in a circular truncated cone shape, a pressure relief area is arranged at the upper end of the flow divider, a plurality of liquid channels are arranged on the peripheral surface of the flow divider, and the pressure relief area is communicated with the liquid channels;

the lower surface of the shell is provided with a plurality of fog outlet membranes, the fog outlet membranes are communicated with the atomizer, and the fog outlet membranes are arranged in an array manner;

the fog outlet membrane is fixed on the base, the base is in threaded connection with the shell through a base fixing part, the fog outlet membrane is communicated with the working area of the atomizer, and the liquid channels are in one-to-one correspondence with the atomizer and the fog outlet membrane.

Preferably, the method further comprises the following steps: the auxiliary fixing device is arranged in the groove I;

the auxiliary fixing device includes:

the end, far away from the indoor space wall, of the fixed rod is fixedly connected to one side, far away from the indoor space wall, of the inner wall of the groove, and a driving assembly is installed at one end, close to the indoor space wall, of the fixed rod;

the drive assembly includes: the fixing device comprises a mounting plate, an arc-shaped groove, a sliding rod, a connecting spring and a rotating shaft, wherein one end, close to an indoor space, of the fixing rod is rotatably connected with the mounting plate through the rotating shaft, the arc-shaped groove is formed in the mounting plate, the sliding rod is arranged in the arc-shaped groove and is in sliding connection with the arc-shaped groove, one end of the connecting spring is fixedly connected with the sliding rod, and the other end of the connecting spring is fixedly connected with the inner wall of the arc-shaped groove;

the first driving motor is fixedly connected to the front wall of the mounting plate, and an output shaft of the first driving motor is fixedly connected with the rope wheel;

the reversing wheel is rotatably connected to the front wall of the mounting plate and is positioned on one side, close to the indoor space, of the arc-shaped groove;

one end of the steel wire rope is connected with the rope wheel, and the other end of the steel wire rope is wound on the outer wall of the reversing wheel and then fixedly connected with the sliding rod;

one end, far away from the indoor space, of the first connecting rod is hinged to the sliding rod, and the other end of the first connecting rod is hinged to the arc-shaped fixing thorn block;

the second connecting rod is fixedly connected with the arc-shaped fixed thorn block, one end of a hydraulic rod is fixedly connected with the second connecting rod, and the other end of the hydraulic rod is fixedly connected with a piston;

the hydraulic cylinder is fixedly connected with the side wall of the first connecting rod through a plurality of hydraulic cylinder connecting rods, a piston and a reset spring are arranged in the hydraulic cylinder, the piston is connected with the inner wall of the hydraulic cylinder in a sliding manner, one end of the reset spring is fixedly connected with the upper end of the inner wall of the hydraulic cylinder, and the other end of the reset spring is fixedly connected with the piston.

Preferably, the method further comprises the following steps: a second groove is formed in one side, close to the indoor space wall, of the rear portion of the mounting base, and the auxiliary fixing device is arranged in the second groove;

the buffer assembly includes:

one end of the connecting block, which is far away from the indoor space wall body, is fixedly connected with the upper ends of the two inner walls of the grooves, and one end of the connecting block, which is close to the indoor space wall body, is fixedly connected with a rubber pad;

the rectangular connecting block is fixedly connected with the side wall of the connecting block;

one ends of a first rotating rod and a second rotating rod are hinged with the holding rod, and the other ends of the first rotating rod and the second rotating rod are hinged with the rectangular connecting block;

the connector is arranged on the holding pole, one end of a contraction spring is fixedly connected with the connector, and one end of the contraction spring is fixedly connected with the middle part of the second rotating rod;

one end of each elastic rod is hinged with the lower end of the holding rod, and the other end of each elastic rod is hinged with the trapezoidal fixing block;

the upper end of the telescopic rod is fixedly connected with the lower end of the trapezoidal fixed block, and the lower end of the telescopic rod is fixedly connected with the hollow cavity block;

the hollow cavity block is internally provided with: the connecting spring, the upper fixing clamping block, the lower fixing clamping block, the rectangular cushion block and the polyurethane cushion pad are connected;

one end, far away from the connecting block, of the connecting spring is fixedly connected with the inner wall of the hollow cavity block, the other end of the connecting spring is fixedly connected with the upper fixing clamping block, the polyurethane cushion pad is fixedly connected between the upper fixing clamping block and the lower fixing clamping block, one end, far away from the connecting block, of the lower fixing clamping block is fixedly connected with the rectangular cushion block, and the lower end of the rectangular cushion block is fixedly connected with the inner wall of the hollow cavity block;

and one end of the outer wall of the hollow cavity block, which is far away from the connecting block, is in contact with the wall body of the indoor space.

Preferably, the method comprises:

step 1: the intelligent humidification control system controls liquid to flow into a liquid storage cavity of the atomization module through the liquid pipeline II and a liquid inlet channel of the atomization module through the control module;

step 2: after the liquid is divided by a flow divider in the liquid storage cavity, the liquid is supplied to a plurality of working areas of the atomizers communicated with the liquid storage cavity;

and step 3: after the liquid in the working area of the atomizer is atomized by the atomizer, the atomized liquid is discharged to the external environment through the fog outlet membrane.

Drawings

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

FIG. 2 is a schematic diagram of the external structure of the micro-porous atomizer according to the present invention;

FIG. 3 is a schematic diagram of an external structure of the control module according to the present invention;

FIG. 4 is a schematic diagram of a control module according to the present invention;

FIG. 5 is a schematic view of an atomizing module according to the present invention;

FIG. 6 is a schematic diagram of the external structure of the atomizing module according to the present invention;

FIG. 7 is a schematic sectional view of an atomization module according to the present invention;

FIG. 8 is a schematic bottom view of an atomizing module according to the present invention;

FIG. 9 is a left side schematic view of the external structure of the control module and the atomizing module according to the present invention;

FIG. 10 is a schematic view of the control principle of the present invention;

FIG. 11 is a schematic view of the auxiliary fixture and the buffer assembly in the installed position;

FIG. 12 is a schematic view of the auxiliary fastening device according to the present invention after being retracted;

FIG. 13 is a schematic view of an auxiliary fixture according to the present invention;

FIG. 14 is a schematic view of a cushion assembly according to the present invention;

fig. 15 is an enlarged view of a structure shown in fig. 14.

In the figure: 1. a microporous atomizer; 2. an indoor space; 3. a first liquid pipeline; 4. a temperature and humidity detection module; 5. a human body induction module; 6. an air monitoring module; 7. a central fluid infusion system; 8. an intelligent humidification control system; 9. a second liquid pipeline; 10. installing a base; 11. mounting holes; 12. an atomization module; 121. a housing; 122. a liquid inlet channel; 123. a liquid storage cavity; 124. an atomizer working area; 125. an atomizer; 126. a flow divider; 127. mounting grooves; 128. a fog outlet membrane; 129. a base; 1210. a pressure relief area; 1211. a liquid channel; 1212. a base fixture; 13. a lower housing; 14. an upper housing; 15. a first pipe orifice; 16. a through hole; 17. a second pipe orifice; 18. a wire plug; 19. a three-way valve; 20. a pressure reducing valve; 21. a throttle valve; 22. An electromagnetic valve; 23. a control panel; 24. connecting a first pipeline; 25. a second connecting pipeline; 26. a first elbow; 27. A municipal water supply pipeline; 28. a second elbow; 29. a third connecting pipeline; 30. a wire; 31. a first groove; 32. A fixing rod; 33. mounting a plate; 34. an arc-shaped slot; 35. a slide bar; 36. a connecting spring; 37. a rotating shaft; 38. a first driving motor; 39. a sheave; 40. a reversing wheel; 41. a wire rope; 42. a first connecting rod; 43. an arc-shaped fixed thorn block; 44. a second connecting rod; 45. a hydraulic lever; 46. a piston; 47. a hydraulic cylinder; 48. a return spring; 49. a hydraulic cylinder connecting rod; 50. a second groove; 51. connecting blocks; 52. a rubber pad; 53. a rectangular connecting block; 54. holding a pole; 55. a connector; 56. a first rotating lever; 57. a second rotating lever; 58. a retraction spring; 59. an elastic rod; 60. a trapezoidal fixed block; 61. a telescopic rod; 62. a hollow cavity block; 63. a connecting spring; 64. fixing a clamping block; 65. a lower fixed clamping block; 66. a rectangular cushion block; 67. A polyurethane cushion.

Detailed Description

The description of the present invention as to "first", "second", etc. is for descriptive purposes only, and not for purposes of particular ordinal or sequential meaning, nor for limitations, and is intended to identify components or operations described in the same technical language, but is intended to be construed as indicating or implying any relative importance or implicit identification of any number of technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions and technical features between various embodiments can be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present invention.

Example 1

The embodiment of the present invention provides an atomization module for a fresh air system and an atomization method thereof, referring to fig. 1, the present invention provides a technical solution, wherein the atomization module for the fresh air system comprises: micropore atomizer 1, it is a plurality of 1 array of micropore atomizer are installed in 2 interior spaces (can be on the wall body), and is a plurality of through 3 intercommunications of a plurality of liquid pipeline between the micropore atomizer 1, be equipped with intelligent induction system, central fluid infusion system 7 and intelligent humidification control system 8 on the wall body 2, intelligent humidification control system 8 is connected with intelligent induction system, central fluid infusion system 7 electricity respectively.

This application can use at big space environment such as sitting room, office, meeting room, and the humidification simultaneously of a plurality of spatial position is realized to the design of multiple spot distributing type, and whole environment can both be even, wholly reach the effect between comfortable humidity interval, solves the big pain point of current humidifier distance near humidity difference.

This application uses micropore atomizing piece, and the flat piece can minimize product volume on year-on-year basis, and overall structure designs simply relatively.

The beneficial effects of the above technical scheme are: connect a plurality of micropore atomizers 1 as a whole through liquid pipeline 3, then pass through sensor acquisition environmental information by intelligent induction system, intelligent humidification control system 8 is according to the environmental information automatically regulated intelligent regulation atomizer's that the sensor gathered atomization effect, and then realizes that the new trend system guarantees indoor constant humidity and clean purpose all the time under energy-conserving circumstances. The invention solves the following problems: the large space humidification requires a large amount of mist, and if the super-large amount of mist is concentrated on one point for humidification, a large humidity difference is generated due to the distance.

Example 2

On the basis of embodiment 1, please refer to fig. 1, further comprising: a plurality of micropore atomizers 1 and a plurality of liquid pipeline 3 set up on the wall body of 2 optional positions in interior space, two 9 one ends of liquid pipeline run through the wall body of interior space 2 with a plurality of micropore atomizers 1's one end is connected, central authorities ' fluid infusion system 7 passes through two 9 other ends of liquid pipeline with a plurality of micropore atomizers 1's other end intercommunication.

The beneficial effects of the above technical scheme are: according to the invention, by arranging the central liquid supplementing system 7 and the intelligent humidification control system 8, the intelligent humidification control system 8 can control the central liquid supplementing system 7 and the micropore atomizer 1 through data monitored by the intelligent sensing device, so that the atomization effect can be automatically adjusted;

the micro-hole atomizer 1 can be installed in different ways (such as wall-hung type, ceiling type, wall-embedded type, table type, floor type, etc.) according to the use requirements, and the different installation ways can adopt different central liquid supplementing systems 7 (such as centralized water tank water supply, single water tank water supply, tap water supply, etc.).

The control method enables a user to control the atomization module of the fresh air system without manual operation, is more convenient to use, improves the use feeling of the user on the atomization module of the fresh air system, has the characteristics of convenience and novelty in control, sensitive control, safety, reliability and simplicity in operation, and has a good popularization prospect.

Example 3

On the basis of any one of embodiments 1-2, please refer to fig. 2, further comprising: the micro-porous atomizer 1 includes: the installation base 10, a plurality of mounting holes 11 have been seted up to installation base 10 up end, a plurality of atomizing module 12 with a plurality of the mounting holes 11 one-to-one installation.

The working principle and the beneficial effects of the technical scheme are as follows: when the atomization module 12 needs to be installed, an operator can connect the atomization module 12 and the installation hole 11 together by buckling the atomization module and the installation hole, and the setting operation is simple and convenient.

Example 4

On the basis of any one of embodiments 1 to 3, please refer to fig. 1, which further includes: the intelligent sensing device comprises: temperature and humidity measurement module 4, human response module 5, air monitor module 6, temperature and humidity measurement module 4, human response module 5, air monitor module 6 respectively with intelligence humidification control system 8 electricity is connected.

The working principle and the beneficial effects of the technical scheme are as follows:

the temperature and humidity detection module 4 is used for collecting indoor temperature and humidity data;

the human body induction module 5 is used for inducing whether a moving person exists in the room;

the air monitoring module 6 is used for monitoring indoor air quality data; the air monitoring module 6 can be an air quality sensor, which is also called an air environment comprehensive monitor and mainly monitors the values of temperature, humidity, air pressure, illumination, PM2.5, PM10, TVOC and the like in the air, and the gas concentrations of oxygen (O2), carbon dioxide (CO 2), carbon monoxide (CO), formaldehyde (CH 2O) and the like.

Be equipped with in the intelligence humidification control system 8: the device comprises a judgment module and a control module;

the judging module is used for comparing the data from the temperature and humidity detection module 4 and the air monitoring module 6 with a preset reference temperature and humidity data range and an air quality data range;

the temperature and humidity detection module 4 can accurately provide real-time indoor temperature and humidity data and feed back the real-time indoor temperature and humidity data to the intelligent humidification control system 8 in time, and help a user to master and adjust the environmental temperature and humidity conditions in an area in time;

the air quality data detected by the air monitoring module 6 may be: the concentration of PM2.5, the concentration of formaldehyde, the concentration of ammonia and other pollutant data which are harmful to human bodies can be set according to actual use conditions, indoor air pollution can be accurately monitored and analyzed in real time, and the environment air quality condition in the palm area of a user can be helped;

according to the comparison result between the data collected by the temperature and humidity detection module 4 and the air monitoring module 6 and the preset reference temperature and humidity data range and the air quality data range, the intelligent humidification control system 8 controls the central liquid supplementing system 7 and the micropore atomizer 1 to realize automatic adjustment of the atomization effect;

when a user sets required humidity, when a human body induction module 5 judges that a movable person exists in a room, the temperature and humidity detection module 4 can continuously detect and collect indoor temperature and humidity data and transmit the indoor temperature and humidity data back to a judgment module of the intelligent humidification control system 8, according to the comparison result of the data collected by the temperature and humidity detection module 4 and the air monitoring module 6 and the preset reference temperature and humidity data range and the air quality data range, the intelligent humidification control system 8 controls the central liquid supplementing system 7 and the micropore atomizer 1 to realize the automatic adjustment atomization effect, the current default comfortable humidity is 55%, 8 micropore atomizers 1 are fully opened, the humidity is switched to a half-open mode after reaching, the full-open mode is recovered when the humidity is reduced to be lower than 40%, the fog is stopped when the humidity is higher than 65%, the environmental information collected by an indoor sensor, the atomization effect of the atomizer is intelligently adjusted, and the purpose of ensuring indoor constant humidity and cleanness all the time under the energy-saving condition of a fresh air system is further realized.

Example 5

Referring to fig. 2 to 4, the method according to any one of embodiments 1 to 4 further includes:

the installation mode of the atomization module 12 and the installation hole 11 is as follows: any one of screw thread, rotary buckle, push-pull, magnetic attraction and press buckle.

Installation base 10 is connected with the control module group, the control module group is connected with 8 electricity of intelligent humidification control system, the control module group includes: the device comprises a lower shell 13 and an upper shell 14, wherein the lower shell 13 is fixedly connected with the upper shell 14, a first pipe orifice 15 is arranged at the front end of the lower shell 13, a through hole 16 and a second pipe orifice 17 are arranged at the right end of the lower shell 13, and a lead plug 18 penetrates through the through hole 16;

the cavity formed by the lower shell 13 and the upper shell 14 is internally provided with: a three-way valve 19, a pressure reducing valve 20, a throttle valve 21, an electromagnetic valve 22 and a control panel 23;

the right end of the three-way valve 19 is connected with a first connecting pipeline 24 through a second pipe orifice 17, the left end of the three-way valve 19 is connected with the right end of the pressure reducing valve 20 through a second connecting pipeline 25, and the lower end of the three-way valve 19 is connected with one end of the electromagnetic valve 22 through a first elbow 26;

the left end of the pressure reducing valve 20 is connected with a municipal water supply pipeline 27;

the other end of the electromagnetic valve 22 is connected with one end of the throttle valve 21 through a second elbow 28;

one end of a third connecting pipeline 29 penetrates through the first pipe orifice 15 to be connected with the other end of the throttle valve 21, and the other end of the third connecting pipeline 29 is connected with the atomizing module 12;

one end of the control board 23 is electrically connected with the wire plug 18, and the other end of the control board 23 is electrically connected with the atomization module 12 through a wire 30.

The working principle and the beneficial effects of the technical scheme are as follows: when the control module works, according to preset indoor required temperature and humidity, then according to sensor set environmental information in the intelligent sensing device, whether the atomization effect of the atomizer needs to be automatically adjusted and adjusted is judged, when the humidity needs to be increased, the control panel 23 receives a signal to open the electromagnetic valve 22, when water flows through the pressure reducing valve and the three-way valve 19 and enters the throttle valve 21, the opening amplitude (namely the size of the water flow) of the throttle valve 21 is controlled through an external operation signal collected by the control panel 23, and then the water flows through the orifice one 15 and the connecting pipeline three 29 and enters the atomization module 12;

the control module group has contained feed liquor end hydraulic control, feed liquor volume control, liquid business turn over on-off control, height liquid level control, multi-device concatenate, and reposition of redundant personnel function and fluid infusion control, specifically is: the three-way valve 19 realizes series connection and shunt, the pressure reducing valve 29 realizes output hydraulic control, the throttle valve 21 realizes output liquid flow control, the electromagnetic valve 22 realizes the liquid on-off function, and the control panel 23 collects a water level signal, an external operation signal and a humidity monitoring module feedback signal to carry out liquid supplementing and spray head atomization device work start-stop control on the electromagnetic valve.

The hydraulic control purpose is as follows: all liquid involving structures at the rear end do not bear high hydraulic impact, the whole structure of the spray head is prevented from leaking, and the fog film is prevented from leaking;

liquid amount control purpose: the rear end spray nozzle is prevented from spraying the film piece to leak;

the purpose of on-off control is as follows: after signals (high and low water levels) are collected, a control program is used for calculating to start liquid supplement as required;

the atomizer starts and stops control: through the delayed start design, when the atomizer is started, the plurality of fog outlet sheets can synchronously produce fog, and through the delayed stop design, the emptying operation of the working liquid cavity of the spray head is realized;

the technology is characterized in that a plurality of devices can be connected in series (namely, the devices are connected in series through a connecting pipeline I24), each device can work independently or jointly, the processing requirement of a local space (small space) can be met, and the centralized processing of an ultra-large space can also be met, and the technology is characterized in that a main liquid passage of a control module group is connected in series, and the devices are connected in parallel in the main passage (as shown in figure 10);

the micropore atomization module is detachable, when the micropore atomization module is abnormal (atomization amount is obviously reduced), the micropore atomization module can be quickly replaced to achieve the atomization effect of initial delivery, and the detachable mode can be threaded connection, turnbuckle connection, push-pull connection, magnetic attraction connection, press-buckle connection and the like, but the connection mode includes but is not limited to the modes;

the humidity and the temperature of the space reach reasonable standards by setting the number and the positions of the micropore atomizers 1, detecting the temperature and the humidity in a constant space and assisting an intelligent control system;

the water supply system of the micropore atomizer 1 can also be: the water can be supplied in a single direction or in a circulating manner.

Example 6

Referring to fig. 5-10 in addition to any one of embodiments 1-5, the atomization module 12 includes:

a liquid storage cavity 123 and a plurality of atomizer working areas 124 communicated with the liquid storage cavity 123 are arranged in the shell 121, a liquid inlet channel 122 is arranged on the upper surface of the shell 121, liquid enters the liquid storage cavity 123 from the liquid inlet channel 122, the liquid is provided for the atomizer working areas 124 through the liquid storage cavity 123, and the liquid inlet channel 122 is connected with the third connecting pipeline 29;

a plurality of atomizers 125 are integrated at the bottom of the shell 121, an atomizer working area 124 is arranged on the inner bottom surface of the shell 121, one part of the atomizers 125 is arranged at the outer side of the bottom of the shell 121, and the other part of the atomizers 125 is arranged in the atomizer working area 124;

a flow divider 126 is arranged in the liquid storage cavity 123, an installation groove 127 is arranged on the inner top surface of the liquid storage cavity 123, the top end of the flow divider 126 is fixedly connected in the installation groove 127, and the top of the installation groove 127 is communicated with the liquid inlet channel 122;

the flow divider 126 is in a circular truncated cone shape, a pressure relief area 1210 is arranged at the upper end of the flow divider 126, a plurality of liquid channels 1211 are arranged on the peripheral surface of the flow divider 126, and the pressure relief area 1210 is communicated with the liquid channels 1211;

a plurality of mist outlet membranes 128 are arranged on the lower surface of the housing 121, the mist outlet membranes 128 are communicated with the atomizer 125, and the mist outlet membranes 128 are arranged in an array;

the atomizing diaphragm 128 is fixed on the base 129, the base 129 is in threaded connection with the housing 121 through a base fixing member 1212, the atomizing diaphragm 128 is communicated with the atomizer working area 124, and the liquid channel 1211 corresponds to the atomizer 128 and the atomizing diaphragm 128 one to one.

The working principle and the beneficial effects of the technical scheme are as follows: a plurality of atomizers 125 are integrated in the shell 121 and provided with a liquid storage cavity 123, working areas of the atomizers 125 are in the integrated working liquid cavity, liquid enters the liquid storage cavity 123 through the liquid inlet channel 122 and flows to the atomizers 123 communicated with the liquid storage cavity 123 through the liquid storage cavity 123, when the atomizers 125 work, the atomizers atomize the liquid in the liquid storage cavity 123 and humidify the external environment, when the atomizer is used in a large space, a liquid supply source of the liquid inlet channel 4 can be tap water, and the tap water continuously supplies the liquid into the liquid storage cavity 123;

the mist outlet membranes 128 are mounted on the same base 129 to form an integrated module, replacement operation is carried out by taking the integrated membrane as a whole, the operation is convenient and fast, liquid enters a pressure relief area 1210 on the flow divider 126 through the liquid inlet channel 122 to relieve pressure so as to avoid directly acting on the mist outlet membranes 128 to generate pressure action and cause leakage, a plurality of independent liquid channels 1211 distributed on the flow divider 126 are directly oriented to working points of the atomizers 125, the liquid subjected to pressure relief directly supplies liquid for the atomizers 125 through the channels to achieve the purpose of synchronous liquid supply, and the mist outlet membranes 128 can be arranged and combined according to different shapes so as to meet the requirements of achieving large mist quantity, uniformity and fast humidification for a large space;

through the design of above-mentioned structure, inlet channel 4 is used for making liquid get into stock solution chamber 2 to supply liquid to the workspace 3 of a plurality of atomizers simultaneously, but make the workspace 3 of a plurality of atomizers simultaneous workings, realize the multiple spot humidification of humidification module, enlarge the scope of humidification, and reduce the humidity difference of treating among the humidification environment.

Example 7

Referring to fig. 11 to 13, on the basis of any one of embodiments 1 to 6, further comprising: a first groove 31 is formed in one side, close to the wall body of the indoor space 2, of the rear portion of the mounting base 10, and the auxiliary fixing device is arranged in the first groove 31;

the auxiliary fixing device includes:

one end, far away from the wall body of the indoor space 2, of the fixing rod 32 is fixedly connected to one side, far away from the wall body of the indoor space 2, of the inner wall of the first groove 31, and a driving assembly is installed at one end, close to the wall body of the indoor space 2, of the fixing rod 32;

the drive assembly includes: the fixing rod 32 comprises a mounting plate 33, an arc-shaped groove 34, a sliding rod 35, a connecting spring 36 and a rotating shaft 37, wherein one end, close to the indoor space 2, of the fixing rod is rotatably connected with the mounting plate 33 through the rotating shaft 37, the arc-shaped groove 34 is formed in the mounting plate 33, the sliding rod 35 is arranged in the arc-shaped groove 34 and is in sliding connection with the arc-shaped groove, one end of the connecting spring 36 is fixedly connected with the sliding rod 35, and the other end of the connecting spring 36 is fixedly connected with the inner wall of the arc-shaped groove 34;

the first driving motor 38, the first driving motor 38 is fixedly connected to the front wall of the mounting plate 33, and an output shaft of the first driving motor 38 is fixedly connected with a rope pulley 39;

the reversing wheel 40 is rotatably connected to the front wall of the mounting plate 33 and is positioned on one side of the arc-shaped groove 34 close to the indoor space 2;

one end of the steel wire rope 41 is connected with the rope wheel 39, and the other end of the steel wire rope 41 is wound on the outer wall of the reversing wheel 40 and then is fixedly connected with the sliding rod 35;

one end of the first connecting rod 42, which is far away from the indoor space 2, is hinged to the sliding rod 35, and the other end of the first connecting rod 42 is hinged to the arc-shaped fixed thorn block 43;

the second connecting rod 44 is fixedly connected with the arc-shaped fixed thorn block 43, one end of a hydraulic rod 45 is fixedly connected with the second connecting rod 44, and the other end of the hydraulic rod 45 is fixedly connected with a piston 46;

pneumatic cylinder 47, pneumatic cylinder 47 through a plurality of pneumatic cylinder connecting rods 49 with first connecting rod 42 lateral wall fixed connection, be equipped with piston 46 and reset spring 48 in the pneumatic cylinder 47, piston 46 with pneumatic cylinder 47 inner wall sliding connection, reset spring 48 one end with pneumatic cylinder 47 inner wall upper end fixed connection, the reset spring 48 other end with piston 46 fixed connection.

The working principle and the beneficial effects of the technical scheme are as follows: when the microporous atomizer 1 is installed on the shell 2, in order to facilitate fixed installation, the back of the installation base 10 is close to the shell 2, the first driving motor 38 is started to drive the rope pulley 39 to rotate, at this time, the steel wire rope 41 pulls the slide rod 35 through the reversing wheel 40, the slide rod 35 moves obliquely downwards in the arc-shaped groove 34, the connecting spring 36 is stressed to generate elastic potential energy, the first connecting rod 42 extends out of the first groove 31 under the driving of the slide rod 35, hydraulic oil can be injected into the hydraulic cylinder 47 in order to pierce the arc-shaped fixing thorn block 43 into the shell 2, the piston 46 moves downwards under the driving of the hydraulic oil pressure, the hydraulic rod 45 is driven to move downwards by the downward movement of the piston 46, and the second connecting rod 44 is driven to move by the downward movement of the hydraulic rod 45, second connecting rod 44 can drive two sets of fixed thorn pieces 43 of arc and draw close to the centre when moving, will pierce the fixed thorn piece 43 of arc in casing 2 like this (as figure 11), when micropore atomizer 1 is dismantled to needs, can be to the reverse hydraulic oil that injects of pneumatic cylinder 47, under oil pressure and reset spring 48's resilience effect, piston 46 upward movement can drive hydraulic stem 45 upward movement, hydraulic stem 45 upward movement can drive second connecting rod 44 motion, second connecting rod 44 motion can drive the fixed thorn piece 43 of arc and separately to the outside, a driving motor 38 reversal simultaneously, part through wire rope 41 with first connecting rod 42 lower extreme resets the original condition (as figure 12), the device's setting can conveniently be with micropore atomizer 1 fixed mounting on casing 2, and is convenient and fast.

Example 8

Referring to fig. 14-15, in addition to any one of embodiments 1-7, the method further includes: a second groove 50 is formed in one side, close to the wall body of the indoor space 2, of the rear part of the mounting base 10, and an auxiliary fixing device is arranged in the second groove 50;

the buffer assembly includes:

one end, far away from the wall body of the indoor space 2, of the connecting block 51 is fixedly connected with the upper end of the inner wall of the second groove 50, and one end, close to the wall body of the indoor space 2, of the connecting block 51 is fixedly connected with a rubber pad 52;

the rectangular connecting block 53 is fixedly connected with the side wall of the connecting block 51;

one end of each of the first rotating rod 56 and the second rotating rod 57 is hinged to the holding rod 54, and the other end of each of the first rotating rod 56 and the second rotating rod 57 is hinged to the rectangular connecting block 53;

the connecting head 55 is arranged on the holding pole 54, one end of a contraction spring 58 is fixedly connected with the connecting head 55, and one end of the contraction spring 58 is fixedly connected with the middle part of the second rotating rod 57;

one end of each elastic rod 59 is hinged with the lower end of the holding pole 54, and the other end of each elastic rod 59 is hinged with the trapezoidal fixing block 60;

the upper end of the telescopic rod 61 is fixedly connected with the lower end of the trapezoidal fixing block 60, and the lower end of the telescopic rod 61 is fixedly connected with the hollow cavity block 62;

the hollow cavity block 62 is internally provided with: a connecting spring 63, an upper fixing clamping block 64, a lower fixing clamping block 65, a rectangular cushion block 66 and a polyurethane cushion pad 67;

one end, far away from the connecting block 51, of the connecting spring 63 is fixedly connected with the inner wall of the hollow cavity block 62, the other end of the connecting spring 63 is fixedly connected with the upper fixing clamping block 64, the polyurethane cushion 67 is fixedly connected between the upper fixing clamping block 64 and the lower fixing clamping block 65, one end, far away from the connecting block 51, of the lower fixing clamping block 65 is fixedly connected with the rectangular cushion block 66, and the lower end of the rectangular cushion block 66 is fixedly connected with the inner wall of the hollow cavity block 62;

one end of the outer wall of the hollow cavity block 62 far away from the connecting block 51 is in contact with the wall of the indoor space 2.

The working principle and the beneficial effects of the technical scheme are as follows: when the micropore atomizer 1 is installed on the shell 2, an operator can hold the installation base 10 by hand to enable the back of the installation base 10 to be close to the shell 2 and give a certain pressure to the shell, when the installation base 10 is pressed, the connecting block 51 drives the rubber pad 52 to move towards the direction close to the trapezoid fixing block 60, at the moment, the first rotating rod 56 and the second rotating rod 57 arranged on the rectangular connecting block 53 can drive the holding rod 54 to move downwards in an inclined mode, the contraction spring 58 is stressed to store energy, when the rubber pad 52 is in contact with the trapezoid fixing block 60, a part of pressure can be counteracted, when hydraulic oil is injected into the hydraulic cylinder 47, the two groups of arc-shaped fixed stabs 43 draw close towards the middle, meanwhile, pressure can be continuously given to the connecting block 51, the telescopic rod 61 is compressed through the trapezoid fixing block 60, and the pressure is transmitted to the hollow cavity block 62, the connecting spring 63 in the hollow cavity block 62 is compressed by force and disperses the pressure to the polyurethane buffer 67 through the upper fixing clamp block 64 and the lower fixing clamp block 65, wherein the first rotating rod 56 and the second rotating rod 57 are arranged to disperse the vertical downward pressure to both sides, the elastic rods 59 are arranged to absorb the pressure on both sides received by the holding rod 54 when the holding rod moves obliquely downward and to generate bending deformation for energy storage, the arrangement of the connecting spring 63 and the polyurethane buffer 67 in the hollow cavity block 62 at the lower end can reduce the pressure generated when hydraulic oil is injected into the hydraulic cylinder 47 and the two groups of arc-shaped fixing thorn blocks 43 are closed to the middle, and the arrangement of the device can reduce the pressure received when the micropore atomizer 1 is installed and plays a role in protecting the micropore atomizer 1.

Example 9

The method of any one of embodiments 1 to 8, further comprising:

step 1: the intelligent humidification control system controls liquid to flow into a liquid storage cavity of the atomization module through the liquid pipeline II and a liquid inlet channel of the atomization module through the control module;

and 2, step: after the liquid is divided by a flow divider in the liquid storage cavity, the liquid is supplied to a plurality of working areas of the atomizers communicated with the liquid storage cavity;

and 3, step 3: after the liquid in the atomizer working area is atomized by the atomizer, the liquid is discharged to the external environment through the fog outlet membrane.

The beneficial effects of the above technical scheme are: through this atomization method, make the atomizer during operation, it can atomize the liquid of workspace, then carry out the humidification to external environment, when using in great space, constantly provide liquid to integrated working solution intracavity through the running water, when liquid enters into the stock solution intracavity by inlet channel, can shunt in the stock solution intracavity, then supply liquid to the atomizer workspace simultaneously, make the atomizer begin to work simultaneously, the play fog volume that a plurality of atomizers produced is the same from this, it is more even to go out the fog volume.

Example 10

On the basis of any one of embodiments 1 to 9, further comprising:

the first flow sensors are respectively arranged at the mist outlet membranes 128 in a one-to-one correspondence manner and are used for detecting the flow rate of water mist passing through the mist outlet membranes 128 (namely the flow rate of water mist entering a room after passing through the mist outlet membranes 128);

a first flow rate sensor, disposed in the liquid inlet passage 122, for detecting a flow rate of water passing through the liquid inlet passage 122;

a second flow rate sensor, disposed at the outlet of the micro-pore atomizer 1, for detecting an initial velocity of the water mist passing through the outlet of the micro-pore atomizer 1 (the outlet is communicated with the mist outlet membrane 128, i.e. the velocity of the water mist passing through the outlet and then passing through the mist outlet membrane 128);

the timer is arranged at the micropore atomizer 1 and used for detecting the working time of the micropore atomizer 1;

the controller and the alarm are arranged on the outer wall of the micropore atomizer 1, and the controller is electrically connected with the flow sensor I, the flow velocity sensor II, the timer and the alarm;

the controller controls the alarm to work based on the flow sensor I, the flow velocity sensor II and the timer, and the method comprises the following steps:

step 1: calculating the atomization capacity coefficient of the microporous atomizer 1 (namely the efficiency of a plurality of microporous atomizers 1 in diffusing atomizing gas into a required space in working time) according to the formula (1) and the detection values of the flow sensor I, the flow velocity sensor I and the timer:

wherein gamma is the atomization ability coefficient of the micropore atomizer 1, S ₁ To said fog outWater exit area, L, of diaphragm 128 ₁ Is the thickness, R, of the fogging film 128 ₁ Is the radius, R, of the fogging diaphragm 128 ₂ Is the aperture of the mist outlet hole, K, of the mist outlet diaphragm 128 _x Is the detected value of the first flow sensor, X is the number of the fog-outlet films 128, V ₁ The pi is 3.14, T is the detection value of the timer (the parameter in a detection period can be calculated, the detection value of the timer corresponds to the duration of the detection period), delta is the hardness of the current water quality (namely the concentration of calcium ions and magnesium ions in the water body), and R is the detection value of the flow velocity sensor I ₄ Is the average particle size of the particles in the water body under the ideal state, G is the average mass of single particles in the water body under the ideal state, mu is the Kenusen number of the air, P is the circulation coefficient of the indoor air, and rho ₁ Density of water molecules at standard atmospheric pressure, M mass of single water molecule at standard atmospheric pressure, S ₂ Is a preset space area (corresponding to the preset atomization range area of the micropore atomizer);

step 2: calculating the atomization effect coefficient of the micropore atomizer 1 based on the step 1, the flow velocity sensor II and the formula (2):

wherein, delta is the atomization effect coefficient of the micropore atomizer 1, S ₃ For the area of the mist outlet hole of the micropore atomizer 1, theta is the effective range of the micropore atomizer 1 for spraying water mist, omega is the atomization angle of the water mist, A is the error coefficient of the flow velocity sensor II (the value is more than 0 and less than 1, and the stability factor setting for considering the internal structure of the sensor), V ₂ Is the detected value of the second flow velocity sensor R ₃ Is a preset water mist droplet diameter, K is a preset loss coefficient (the value is more than 0 and less than 1, and can be related to the used time of the mist outlet membrane 128 and the influence of the use environment on the mist outlet membrane 128), and csc is a cosecant value, wherein the loss coefficient is preset by the mist outlet membrane 128;

step three: the controller will micropore atomizer 1's actual atomization effect coefficient is compared with the preset atomization effect coefficient, and when 1 actual atomization effect coefficient of micropore atomizer is less than the preset atomization effect coefficient of electron cigarette, the controller control the alarm sends the suggestion of reporting to the police.

Assuming the water outlet area S of the fogging diaphragm 128 ₁ ＝0.2cm ² Thickness L of the fogging diaphragm 128 ₁ =0.1cm, radius R of the fogging membrane 128 ₁ =0.5cm, and the aperture R of the mist outlet hole on the mist outlet membrane 128 ₂ =0.02cm, and a detection value K of the first flow sensor _x =0.2L/min, the number X =6 of the mist outlet diaphragms 128, and the first flow velocity sensor has a detection value V ₁ =0.5m/s, the timer detection value T =2h, the current water hardness (i.e., the concentration of calcium ions and magnesium ions in the water body) Δ =250mg/L, and the ideal average particle diameter R of the particulate matter contained in the water body ₄ =38 μm, G is the average mass G =1.02mg of the particulate matter contained in the water body in an ideal state, the knudsen number μ =0.01 of the air, the flow coefficient P =0.85 of the indoor air, and the density ρ of the water molecules at the standard atmospheric pressure ₁ ＝1g/cm ³ Mass M =3 × 10 of a single water molecule at standard atmospheric pressure ^-23 g, predetermined space area S ₂ ＝50m ² The atomization ability effect γ =0.64 (two decimal places) of the micro-pore atomizer 1 is calculated by the formula (1).

The area S of the mist outlet hole of the micropore atomizer 1 ₃ ＝0.3cm ² The effective range theta =1m of the water mist sprayed by the micropore atomizer 1, the atomization angle omega =160 degrees of the water mist, the error coefficient A =0.81 of the flow velocity sensor II, and the flow velocity sensor II V ₂ =0.1m/s, predetermined diameter R of water mist droplets ₃ =0.3mm, the loss coefficient K =0.75 preset by the atomizing diaphragm 128, the actual atomization effect coefficient δ =0.76 of the micro-pore atomizer 1 is calculated by the formula (2) (two decimal points are taken), and the actual atomization effect coefficient σ of the micro-pore atomizer 1 is calculated ₂ And the value of 0.53 is less than the preset atomization effect coefficient of 0.85-1, the atomization capacity coefficient of the micropore atomizer 1 is reduced, and the controller controls the alarm to send out an alarm prompt.

Wherein the content of the first and second substances,

shows the influence of the characteristic limit of the particles and the size limit of the fog-outlet diaphragm 128 when the fog-outlet diaphragm 128 carries the particles through the fog-outlet hole under the influence of the moving speed of water molecules when the water fog and the particles contained in the water fog pass through the hole;

and X [ mu ] GM [ S ] ₂ -S ₁ +(L ₁ -R ₁ ) ² ]Shows the influence of the mass of particulate matter carried by a single water molecule under standard atmospheric pressure on the atomization capacity of the microporous atomizer 1 under the limitation of the number and the size of the atomizing film 128 when the mass passes through the atomizing film 128;

then pass through

Calculating to obtain the atomization capacity coefficient of the micropore atomizer 1;

wherein if K is _x And V ₁ When the pressure of the water mist flowing through the mist outlet hole is increased continuously, the atomization capacity coefficient of the micropore atomizer 1 is increased continuously.

Indicating the influence of the difference between the diameter of the mist droplets and the diameter of the mist outlet holes in the mist outlet membrane 128 on the passage of the mist through the mist outlet membrane 128 during the working time T when the mist has the initial velocity of the mist droplets passing through the outlet of the micro-porous atomizer 1,

to account for the rate of flow of liquid through the inlet passage 122 and the coefficient of influence of the mass of particulate matter contained therein on the effective range,

indicating water spray according to actual water mistThe influence state of the volume and the actual effective range of the micro-porous atomizer 1 is calculated with gamma csc omega to obtain the atomization effect coefficient of the micro-porous atomizer 1;

wherein γ csc ω represents that, in the dynamic change process of the atomization angle of the water mist of the micro-pore atomizer 1, when the initial velocity of the water mist at the outlet of the micro-pore atomizer 1 becomes high (i.e. the flow rate and the pressure of the water flow become high), the atomization ability coefficient γ of the micro-pore atomizer 1 also becomes high under the influence of the atomization angle (i.e. the spraying range of the micro-pore atomizer 1 becomes wide), so that

The atomization effect coefficient becomes large under the influence thereof;

then according to

Calculating to obtain an actual atomization effect coefficient after correction, wherein the actual atomization effect coefficient is calculated along with gamma and V ₂ Constantly increase, institute the actual atomization effect coefficient of micropore atomizer 1 also can constantly increase, and when micropore atomizer 1 used, a plurality of goes out fog diaphragm 128 and produces water smoke, utilizes flow sensor one, the flow of time-recorder detection water smoke when passing through a fog diaphragm 128 in the during operation, utilizes flow sensor two, and water smoke passes through the initial velocity of the droplet in the exit of micropore atomizer 1, the controller utilizes formula (1) to calculate the atomization ability coefficient and formula (2) of micropore atomizer 1 calculate the actual atomization effect coefficient of micropore atomizer 1 if the actual atomization effect coefficient of micropore atomizer 1 is less than the preset atomization effect coefficient of electron cigarette, controller control the alarm sends the warning suggestion.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The utility model provides an atomizing module for new trend system which characterized in that includes: the system comprises micropore atomizers (1), a plurality of micropore atomizers (1) are arranged in an indoor space (2) in an array mode, the micropore atomizers (1) are communicated through a plurality of liquid pipelines I (3), an intelligent sensing device, a central liquid supplementing system (7) and an intelligent humidification control system (8) are arranged in the indoor space (2), and the intelligent humidification control system (8) is electrically connected with the intelligent sensing device and the central liquid supplementing system (7) respectively;

the micro-porous atomizer (1) comprises: the atomization device comprises a mounting base (10), wherein a plurality of mounting holes (11) are formed in the upper end face of the mounting base (10), and a plurality of atomization modules (12) are correspondingly mounted in the mounting holes (11) one by one;

further comprising: a first groove (31) is formed in one side, close to the wall body of the indoor space (2), of the rear portion of the mounting base (10), and the auxiliary fixing device is arranged in the first groove (31);

the auxiliary fixing device includes:

one end, far away from the wall body of the indoor space (2), of the fixing rod (32) is fixedly connected to one side, far away from the wall body of the indoor space (2), of the inner wall of the first groove (31), and a driving assembly is installed at one end, close to the wall body of the indoor space (2), of the fixing rod (32);

the drive assembly includes: mounting panel (33), arc wall (34), slide bar (35), coupling spring (36), rotation axis (37), the one end that dead lever (32) are close to indoor space (2) with mounting panel (33) pass through rotation axis (37) rotate the connection, arc wall (34) have been seted up to mounting panel (33), slide bar (35) are located in arc wall (34) and rather than sliding connection, coupling spring (36) one end with slide bar (35) fixed connection, coupling spring (36) other end with arc wall (34) inner wall fixed connection;

the first driving motor (38), the first driving motor (38) is fixedly connected to the front wall of the mounting plate (33), and an output shaft of the first driving motor (38) is fixedly connected with the rope wheel (39);

the reversing wheel (40) is rotatably connected to the front wall of the mounting plate (33) and is positioned on one side, close to the indoor space (2), of the arc-shaped groove (34);

one end of the steel wire rope (41) is connected with the rope wheel (39), and the other end of the steel wire rope (41) is wound on the outer wall of the reversing wheel (40) and then is fixedly connected with the sliding rod (35);

one end, far away from the indoor space (2), of the first connecting rod (42) is hinged to the sliding rod (35), and the other end of the first connecting rod (42) is hinged to the arc-shaped fixing thorn block (43);

the second connecting rod (44) is fixedly connected with the arc-shaped fixed thorn block (43), one end of a hydraulic rod (45) is fixedly connected with the second connecting rod (44), and the other end of the hydraulic rod (45) is fixedly connected with a piston (46);

the hydraulic cylinder (47) is fixedly connected with the side wall of the first connecting rod (42) through a plurality of hydraulic cylinder connecting rods (49), a piston (46) and a return spring (48) are arranged in the hydraulic cylinder (47), the piston (46) is in sliding connection with the inner wall of the hydraulic cylinder (47), one end of the return spring (48) is fixedly connected with the upper end of the inner wall of the hydraulic cylinder (47), and the other end of the return spring (48) is fixedly connected with the piston (46);

further comprising: a second groove (50) is formed in one side, close to the wall body of the indoor space (2), of the rear portion of the mounting base (10), and an auxiliary fixing device is arranged in the second groove (50);

the buffer assembly includes:

one end, far away from the wall body of the indoor space (2), of the connecting block (51) is fixedly connected with the upper end of the inner wall of the second groove (50), and one end, close to the wall body of the indoor space (2), of the connecting block (51) is fixedly connected with a rubber pad (52);

the rectangular connecting block (53), the said rectangular connecting block (53) is fixedly connected with sidewall of the said connecting block (51);

one ends of a first rotating rod (56) and a second rotating rod (57) are hinged to the holding rod (54), and the other ends of the first rotating rod (56) and the second rotating rod (57) are hinged to the rectangular connecting block (53);

the connecting head (55) is arranged on the holding pole (54), one end of a contraction spring (58) is fixedly connected with the connecting head (55), and one end of the contraction spring (58) is fixedly connected with the middle part of the second rotating rod (57);

one end of each elastic rod (59) is hinged with the lower end of the corresponding holding rod (54), and the other end of each elastic rod (59) is hinged with the corresponding trapezoidal fixing block (60);

the upper end of the telescopic rod (61) is fixedly connected with the lower end of the trapezoidal fixed block (60), and the lower end of the telescopic rod (61) is fixedly connected with the hollow cavity block (62);

the hollow cavity block (62) is internally provided with: a connecting spring (63), an upper fixing clamping block (64), a lower fixing clamping block (65), a rectangular cushion block (66) and a polyurethane cushion pad (67);

one end, far away from the connecting block (51), of the connecting spring (63) is fixedly connected with the inner wall of the hollow cavity block (62), the other end of the connecting spring (63) is fixedly connected with the upper fixing clamping block (64), the polyurethane cushion pad (67) is fixedly connected between the upper fixing clamping block (64) and the lower fixing clamping block (65), one end, far away from the connecting block (51), of the lower fixing clamping block (65) is fixedly connected with the rectangular cushion block (66), and the lower end of the rectangular cushion block (66) is fixedly connected with the inner wall of the hollow cavity block (62);

one end, far away from the connecting block (51), of the outer wall of the hollow cavity block (62) is in contact with the wall body of the indoor space (2).

2. The atomizing module for the fresh air system according to claim 1, wherein the plurality of micro-porous atomizers (1) and the plurality of first liquid pipelines (3) are disposed on a wall at any position of the indoor space (2), one end of a second liquid pipeline (9) penetrates through the wall of the indoor space (2) and is connected with one end of the plurality of micro-porous atomizers (1), and the central liquid supplementing system (7) is communicated with the other end of the plurality of micro-porous atomizers (1) through the other end of the second liquid pipeline (9).

3. The atomizing module for new trend system of claim 1, characterized in that, intelligent induction system includes: temperature and humidity measurement module (4), human response module (5), air monitor module (6), temperature and humidity measurement module (4), human response module (5), air monitor module (6) respectively with intelligence humidification control system (8) electricity is connected.

4. An atomizing module for a fresh air system according to claim 1, wherein the atomizing module (12) and the mounting hole (11) are mounted in a manner that: any one of screw thread, rotary buckle, push-pull, magnetic attraction and press buckle.

5. An atomization module for a fresh air system according to claim 3, characterized in that a control module is connected to the mounting base (10), the control module being electrically connected to an intelligent humidification control system (8), the control module comprising: the device comprises a lower shell (13) and an upper shell (14), wherein the lower shell (13) is fixedly connected with the upper shell (14), a first pipe orifice (15) is arranged at the front end of the lower shell (13), a through hole (16) and a second pipe orifice (17) are arranged at the right end of the lower shell (13), and a wire plug (18) penetrates through the through hole (16);

the cavity formed by the lower shell (13) and the upper shell (14) is internally provided with: a three-way valve (19), a pressure reducing valve (20), a throttle valve (21), an electromagnetic valve (22) and a control panel (23);

the right end of the three-way valve (19) is connected with a first connecting pipeline (24) through a second pipe orifice (17), the left end of the three-way valve (19) is connected with the right end of the pressure reducing valve (20) through a second connecting pipeline (25), and the lower end of the three-way valve (19) is connected with one end of the electromagnetic valve (22) through a first elbow (26);

the left end of the pressure reducing valve (20) is connected with a municipal water supply pipeline (27);

the other end of the electromagnetic valve (22) is connected with one end of the throttle valve (21) through a second elbow (28);

one end of a third connecting pipeline (29) penetrates through the first pipe orifice (15) to be connected with the other end of the throttling valve (21), and the other end of the third connecting pipeline (29) is connected with the atomizing module (12);

one end of the control board (23) is electrically connected with the wire plug (18), and the other end of the control board (23) is electrically connected with the atomization module (12) through a wire (30).

6. An atomisation module for a fresh air system according to claim 4, characterised in that the atomisation module (12) comprises:

the liquid supply device comprises a shell (121), wherein a liquid storage cavity (123) and a plurality of atomizer working areas (124) communicated with the liquid storage cavity (123) are arranged in the shell (121), a liquid inlet channel (122) is arranged on the upper surface of the shell (121), liquid enters the liquid storage cavity (123) from the liquid inlet channel (122), the liquid is provided for the atomizer working areas (124) through the liquid storage cavity (123), and the liquid inlet channel (122) is connected with a third connecting pipeline (29);

a plurality of atomizers (125) are integrated at the bottom of the shell (121), an atomizer working area (124) is arranged on the inner bottom surface of the shell (121), one part of the atomizers (125) is arranged at the outer side of the bottom of the shell (121), and the other part of the atomizers (125) is arranged in the atomizer working area (124);

a flow divider (126) is arranged in the liquid storage cavity (123), an installation groove (127) is formed in the inner top surface of the liquid storage cavity (123), the top end of the flow divider (126) is fixedly connected into the installation groove (127), and the top of the installation groove (127) is communicated with the liquid inlet channel (122);

the flow divider (126) is in a circular truncated cone shape, a pressure relief area (1210) is arranged at the upper end of the flow divider (126), a plurality of liquid channels (1211) are arranged on the peripheral surface of the flow divider (126), and the pressure relief area (1210) is communicated with the liquid channels (1211);

the lower surface of the shell (121) is provided with a plurality of fog outlet membranes (128), the fog outlet membranes (128) are communicated with the atomizer (125), and the fog outlet membranes (128) are arranged in an array;

the atomizing membrane (128) is fixed on a base (129), the base (129) is in threaded connection with the shell (121) through a base fixing piece (1212), the atomizing membrane (128) is communicated with the atomizer working area (124), and the liquid channel (1211) corresponds to the atomizer (128) and the atomizing membrane (128) one to one.

7. A method of atomisation for the atomisation module of a fresh air system according to any of the claims 1 to 6, characterised in that: the method comprises the following steps:

step 1: the intelligent humidification control system controls liquid to flow into a liquid storage cavity of the atomization module through the liquid pipeline II and a liquid inlet channel of the atomization module through the control module;

step 2: after the liquid is divided by a flow divider in the liquid storage cavity, the liquid is supplied to a plurality of working areas of the atomizers communicated with the liquid storage cavity;

and step 3: after the liquid in the working area of the atomizer is atomized by the atomizer, the atomized liquid is discharged to the external environment through the fog outlet membrane.

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