CN113877756A

CN113877756A - Active fog ion generating device and control system thereof

Info

Publication number: CN113877756A
Application number: CN202111460794.6A
Authority: CN
Inventors: 肖志国; 刘鹤宁
Original assignee: Beijing Fu Yun Cloud Data Technology Co ltd
Current assignee: Beijing Fu Yun Cloud Data Technology Co ltd
Priority date: 2021-12-02
Filing date: 2021-12-02
Publication date: 2022-01-04
Anticipated expiration: 2041-12-02
Also published as: CN113877756B

Abstract

The invention discloses an active fog ion generating device and a control system thereof, relating to the technical field of air sterilization and disinfection, the device of the invention comprises an atomizing component, a water storage component and a fog outlet component, wherein the atomizing component comprises a base plate, a circuit board arranged on the base plate, a piezoelectric ceramic plate arranged on the upper part of the circuit board and a control module, the water storage component comprises a water storage tank arranged above the base plate, a water inlet pipe arranged on the side wall of the water storage tank and a shaping sponge arranged inside the water storage tank, the fog outlet component comprises a lower electrode plate arranged on the upper part of the water storage tank and an upper electrode plate arranged above the lower electrode plate, the upper part of the lower electrode plate is provided with a circular water storage groove, the bottom of the water storage groove is provided with a water hole, an electrolytic cone is arranged between adjacent water storage grooves, the upper electrode plate is provided with a thin pipe in a penetrating way, the end of the thin pipe is connected with a fog inlet funnel in a penetrating way, the fog inlet funnel is arranged right above the electrolytic cone, the fog inlet funnels correspond to the electrolysis cones one by one, and the invention has better water supply effect and higher active fog ion spraying rate.

Description

Active fog ion generating device and control system thereof

Technical Field

The invention relates to the technical field of air sterilization and disinfection, in particular to an active fog ion generating device and a control system thereof.

Background

Atomization refers to an operation of converting liquid into high-speed airflow to disperse the liquid into tiny droplets, and atomization can be divided into mechanical atomization and medium atomization, wherein mechanical atomization is realized by means of the pressure of the liquid after the liquid leaves an outlet of a nozzle, so the mechanical atomization is also called pressure atomization, and partial other media are mixed before the liquid is sprayed out of a nozzle to change the flowing property and the surface shape of the liquid and play a role in strengthening an atomization process, namely medium atomization.

In current ultrasonic wave mechanical atomization, the ultrasonic atomization technique is because overall structure is succinct, and the even effectual and universal application of droplet is in each field, and the core of ultrasonic atomization technique is the ultrasonic atomization piece, and current ultrasonic atomization piece is binded by piezoceramics crystal (PZT 4) and stainless steel paster (SUS 304) and constitutes, and in the ultrasonic atomization principle, the ultrasonic atomization piece produces resonant frequency, atomizes liquid through resonant frequency's ultrasonic wave.

The existing active mist ion generating device adopts piezoelectric ceramic crystals and stainless steel patches to atomize liquid, so that the liquid cannot enter the stainless steel patches in the mechanical use process, the equipment is troublesome, the intelligent degree of the equipment is low, the active mist ion injection rate is low, and the sterilization and disinfection are poor, so that a new solution is necessary to be provided.

Disclosure of Invention

The invention mainly aims to provide an active mist ion generating device and a control system thereof, which have high intelligent degree, high active mist ion spraying speed and good sterilization and disinfection.

In order to achieve the purpose, the invention adopts the technical scheme that: an active fog ion generating device comprises a device body, wherein the device body comprises an atomizing component, a water storage component and a fog outlet component;

the atomization assembly comprises a substrate, a circuit board arranged on the substrate, a piezoelectric ceramic piece arranged on the upper part of the circuit board and a control module;

the water storage assembly comprises a water storage tank arranged above the base plate, a water inlet pipe arranged on the side wall of the water storage tank and a shaping sponge arranged inside the water storage tank;

go out the fog subassembly including setting up the lower plate electrode on aqua storage tank upper portion, be located the last electrode plate of lower plate electrode top, the lower plate electrode with go up the electrode plate and correspond each other, circular water storage recess has been seted up on lower plate electrode upper portion, and a plurality of water storage groove array distribute, and every water storage recess bottom is equipped with the water hole, and is adjacent be equipped with the electrolysis awl between the water storage recess, it is equipped with the tubule to link up on the last electrode plate, and is a plurality of the tubule becomes array distribution, every tubule end through connection has into fog funnel, advance fog funnel upper end diameter with the tubule diameter is the same, it is greater than its upper end diameter to advance fog funnel lower extreme diameter, and per two and advance the fog funnel lateral wall and closely laminate, every it is located directly over the electrolysis awl, the electrolysis awl one-to-one that the fog funnel that the array distributes and array distribute.

Preferably, go out the fog subassembly and still establish the cage at last electrode plate and lower electrode plate outer wall including the cover, the cage lateral wall is equipped with the spool, the spool lower extreme is connected with the base plate, the spool upper end is passed the cage and is connected with last electrode plate lateral wall, the convex pipe in spool middle part pass the cage with the lower electrode plate lateral wall is connected.

Preferably, a plurality of water outlet heads are arranged at one end of the water inlet pipe, an electromagnetic valve is arranged at the other end of the water inlet pipe, the water outlet heads are divided into two groups, the water outlet heads are symmetrically distributed about the central axis of the water storage tank, and one end of each water outlet head is communicated with the water storage tank.

Preferably, the substrate side wall is provided with a micro pump, the micro pump is provided with a water inlet and a water outlet, the water outlet of the micro pump is connected with the lower end of the water inlet pipe, the water inlet of the micro pump is connected with a connecting pipe, and the lower end of the connecting pipe is provided with a sealing ring and a threaded pipe.

Preferably, the device body still includes the spout subassembly, the spout subassembly includes that it says, goes out the fog pipe to go out the fog, it says for the halfpace structure to go out the fog, inside cavity, and the end opening cross-section is square ring structure, and the end opening cross-section is the ring structure, go out the fog way lower extreme with go up the surface connection of electrode plate, just it says that the length of side of lower extreme size of fog is the same with last electrode plate length of side size, go out the fog pipe lower extreme with it says surface connection to go out the fog, go out the inside and outside wall diameter of fog pipe, with it says that the inside and outside wall diameter of upper opening is the same to go out the fog, just it is equipped with first filter screen to go out the fog pipe top, bar through-hole has been seted up at first filter screen middle part, just bar through-hole low side corner is handled in the circular arc.

Preferably, a plurality of fixing blocks are arranged on the side wall of the mist outlet pipe, the fixing blocks are distributed at equal intervals, and a fixing through hole is formed in the middle of each fixing block.

Preferably, the device body still includes and turns to the subassembly, turn to the subassembly and establish the rotating tube on a fog pipe upper portion including the cover, the rotating tube lower extreme is equipped with a plurality of L shape fixed legs, the equidistant distribution of L shape fixed leg, and with the mutual adaptation of fixed through hole, the rotating tube inner wall is equipped with the leather plug, the leather plug with go out the outer wall of fog pipe and closely laminate.

Preferably, the upper end of the rotating pipe is connected with an elbow pipe in a through mode, one end of the elbow pipe is provided with an air blower, and the other end of the elbow pipe serves as an outlet end and is provided with a second filter screen.

The control system of the active fog ion generating device comprises a control module which is in communication connection with a main system, wherein an identity unit, a wireless receiving unit and a control unit are arranged in the control module;

identity information data are set in the identity units, and the identity information data of different identity units are different;

the wireless receiving unit comprises a signal interface and an instruction interface, the signal interface is used for receiving the digital signal transmitted by the main system and synchronously feeding the digital signal back to the instruction interface, and the instruction interface is used for converting the digital signal into an instruction signal and transmitting the instruction signal to the control unit;

the control unit is control chip, control chip controls piezoceramics piece, solenoid valve and micropump according to instruction signal, whether work and produce load voltage's big or small controlgear through controlling the piezoceramics piece and whether atomize and the degree of atomization size, add the inside liquid volume of aqua storage tank through control solenoid valve and micropump control, the circuit board produces current signal according to instruction signal, current signal transmits to down plate electrode and last electrode plate through spool inside wire, form high-tension electric field between plate electrode and last electrode plate down.

Compared with the prior art, the invention has the following beneficial effects:

the invention sets a water storage tank in the water storage component and a shaping sponge in the water storage tank, when liquid water is added into the water storage tank, water is respectively added into the water outlet tank from two sides of the water storage tank through two sets of water outlets which are oppositely arranged, the water flow is more stable, when a certain amount of liquid water is added, the liquid water fills the water storage tank and permeates into the water storage groove of the lower electrode plate through the water hole of the lower electrode plate, at the moment, the piezoelectric ceramic plate generates ultrasonic wave, the ultrasonic wave oscillation realizes the atomization of the liquid water on the lower electrode plate to generate active molecules, a high-voltage electric field is generated between the upper electrode plate and the lower electrode plate through a wire pipe by generating current through a circuit board, the electrolytic cone generates active fog ions carrying electric charges, the active fog ions move upwards under the action of the electric field force, because an inverted fog inlet funnel is arranged right above each electrolytic cone arranged in the array, active fog ions enter the thin tube through the inverted fog inlet funnel, the active fog ions are pressurized by the fog inlet funnel and then enter the fog outlet channel after passing through the upper electrode plate, the active fog ions are pressurized by the fog outlet channel with the inclined side wall, and the spraying speed of the active fog ions is improved by two times of pressurization, so that the active fog ion spraying device has the advantages of more stable liquid supply, higher fog ion spraying speed and better sterilization and disinfection.

The invention sets a main system and a control module, wherein the main system is internally provided with a display unit and a plurality of wireless transmitting units, one wireless transmitting unit can be matched with a wireless receiving unit of the control module, one control module comprises an identity recognition unit, a control unit and a wireless receiving unit, the main system retrieves the corresponding identity information of the control module, the corresponding wireless receiving unit receives the corresponding data signal by sending the data signal to the wireless transmitting unit, the corresponding data signal is synchronously fed back to the control unit to generate an instruction signal, and the control unit controls the corresponding mechanical work through a control chip according to the instruction signal, so that the main system can simultaneously control a plurality of mist ion generating devices through a wireless Bluetooth system within a certain range, and the active mist ion generating devices are more intelligent.

Drawings

Fig. 1 is a schematic view of the overall structure of an active mist ion generating device according to a first embodiment of the present invention;

FIG. 2 is a schematic front view of an active mist ion generator according to a first embodiment of the present invention;

FIG. 3 is a schematic view of the overall structure of a turning member in the active mist ion generating device according to the first embodiment of the present invention;

FIG. 4 is a schematic top view of a turning assembly of the active mist ion generating device according to the first embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view taken at F-F of FIG. 4 according to the present invention;

FIG. 6 is a schematic view of the overall structure of the lower electrode plate according to the present invention;

FIG. 7 is a schematic top view of the lower electrode plate of the present invention;

FIG. 8 is a schematic cross-sectional view taken along line A-A of FIG. 7 according to the present invention;

FIG. 9 is an enlarged view of the structure of FIG. 6 at B in the present invention;

FIG. 10 is a schematic view showing the overall structure of an upper electrode plate according to the present invention;

FIG. 11 is a schematic bottom view of the upper electrode plate of the present invention;

FIG. 12 is a schematic cross-sectional view taken at C-C of FIG. 11 according to the present invention;

FIG. 13 is an enlarged view of FIG. 10 at D according to the present invention;

FIG. 14 is a schematic view of a connection structure of a substrate and a circuit board according to the present invention;

FIG. 15 is an enlarged view of FIG. 14 at E according to the present invention;

FIG. 16 is a schematic view of the overall structure of an active mist ion generating device according to a second embodiment of the present invention;

FIG. 17 is a schematic top view of an active mist ion generator according to a second embodiment of the present invention;

FIG. 18 is a schematic cross-sectional view taken at G-G of FIG. 17 according to the present invention;

FIG. 19 is an enlarged view of the structure of FIG. 18 at H according to the present invention;

fig. 20 is a schematic view of the overall structure of an active mist ion generating device according to a third embodiment of the present invention:

FIG. 21 is a system block diagram of a control system of the active mist ion generating device of the present invention.

In the figure: 1. a substrate; 2. a circuit board; 3. piezoelectric ceramic plates; 4. a control module; 5. a water storage tank; 6. a water inlet pipe; 7. shaping the sponge; 8. a lower electrode plate; 9. an upper electrode plate; 10. a water storage groove; 11. a water pore; 12. an electrolytic cone; 13. a thin tube; 14. a fog inlet funnel; 15. a water outlet head; 16. an electromagnetic valve; 17. a micro-pump; 18. a connecting pipe; 19. a seal ring; 20. a threaded pipe; 21. a mist outlet channel; 22. a mist outlet pipe; 23. a first filter screen; 24. a fixed block; 25. rotating the tube; 26. an L-shaped fixed leg; 27. bending the pipe; 28. a blower; 29. a second filter screen; 30. an isolation cover; 31. a conduit; 32. a water tank; 33. a liquid outlet pipe; 34. a nut ring; 35. a bottle mouth; 36. and (7) a bottle cap.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example one

Fig. 1 is a schematic diagram of an overall structure of an active mist ion generating device according to a first embodiment of the present invention, please refer to fig. 2-15, and fig. 17-19, the active mist ion generating device according to the present embodiment includes a device body, the device body includes an atomizing assembly, a water storage assembly, a mist outlet assembly, and a steering assembly;

the steering assembly comprises a rotating pipe 25 sleeved on the upper part of the mist outlet pipe 22, a plurality of L-shaped fixing legs 26 are arranged at the lower end of the rotating pipe 25, the L-shaped fixing legs 26 are distributed at equal intervals and are matched with the fixing through holes, a leather plug is arranged on the inner wall of the rotating pipe 25 and is tightly attached to the outer wall of the mist outlet pipe 22, a bent pipe 27 is connected to the upper end of the rotating pipe 25 in a penetrating manner, one end of the bent pipe 27 is provided with an air blower 28, and the other end of the bent pipe 27 serves as an outlet end and is provided with a second filter screen 29; the atomization assembly comprises a substrate 1, a circuit board 2 arranged on the substrate 1, a piezoelectric ceramic piece 3 arranged on the upper part of the circuit board 2 and a control module 4;

the water storage component comprises a water storage tank 5 arranged above the base plate 1, a water inlet pipe 6 arranged on the side wall of the water storage tank 5 and a shaping sponge 7 arranged inside the water storage tank 5;

the fog outlet assembly comprises a lower electrode plate 8 arranged on the upper portion of a water storage tank 5, an upper electrode plate 9 arranged above the lower electrode plate 8, the lower electrode plate 8 corresponds to the upper electrode plate 9, circular water storage grooves 10 are formed in the upper portion of the lower electrode plate 8, the water storage grooves 10 are distributed in an array mode, a water hole 11 is formed in the bottom of each water storage groove 10, an electrolytic cone 12 is arranged between every two adjacent water storage grooves 10, thin pipes 13 are arranged on the upper electrode plate 9 in a penetrating mode, the thin pipes 13 are distributed in an array mode, a fog inlet funnel 14 is connected to the end of each thin pipe 13 in a penetrating mode, the diameter of the upper end of each fog inlet funnel 14 is the same as the diameter of each thin pipe 13, the diameter of the lower end of each fog inlet funnel 14 is larger than the diameter of the upper end of each fog inlet funnel, the side walls of every two fog inlet funnels 14 are tightly attached to each other, each fog inlet funnel 14 is located right above each electrolytic cone 12, and the fog inlet funnels 14 distributed in the array mode correspond to the electrolytic cones 12 distributed in the array mode.

In this embodiment, the fog outlet assembly further includes an isolation cover 30 sleeved on the outer walls of the upper electrode plate 9 and the lower electrode plate 8, a line pipe 31 is disposed on the side wall of the isolation cover 30, the lower end of the line pipe 31 is connected with the base plate 1, the upper end of the line pipe 31 penetrates through the isolation cover 30 to be connected with the side wall of the upper electrode plate 9, and a convex pipe in the middle of the line pipe 31 penetrates through the isolation cover 30 to be connected with the side wall of the lower electrode plate 8.

In this embodiment, one end of the water inlet pipe 6 is provided with a plurality of water outlets 15, the other end of the water inlet pipe 6 is provided with an electromagnetic valve 16, the plurality of water outlets 15 are divided into two groups, the two groups of the plurality of water outlets 15 are symmetrically distributed about the central axis of the water storage tank 5, and one end of each water outlet 15 is communicated with the water storage tank 5.

In this embodiment, the lateral wall of the substrate 1 is provided with a micro pump 17, the micro pump 17 is provided with a water inlet and a water outlet, the water outlet of the micro pump 17 is connected with the lower end of the water inlet pipe 6, the water inlet of the micro pump 17 is connected with a connecting pipe 18, and the lower end of the connecting pipe 18 is provided with a sealing ring 19 and a threaded pipe 20.

In this embodiment, the device body further includes a nozzle assembly, the nozzle assembly includes a mist outlet channel 21 and a mist outlet pipe 22, the mist outlet channel 21 is of a step structure, the inner portion of the mist outlet channel is hollow, the cross section of the lower opening of the mist outlet channel is of a square ring structure, the cross section of the upper opening of the mist outlet channel is of a circular ring structure, the lower end of the mist outlet channel 21 is connected with the upper surface of the upper electrode plate 9, the side length of the lower end of the mist outlet channel 21 is the same as that of the upper electrode plate 9, the lower end of the mist outlet pipe 22 is connected with the surface of the mist outlet channel 21, the diameter of the inner wall and the outer wall of the mist outlet pipe 22 is the same as that of the upper opening of the mist outlet channel 21, the top end of the mist outlet pipe 22 is provided with a first filter screen 23, a bar-shaped through hole is formed in the middle of the first filter screen 23, and the corner of the lower end of the bar-shaped through hole is processed in an arc shape.

In this embodiment, the side wall of the mist outlet pipe 22 is provided with a plurality of fixing blocks 24, the fixing blocks 24 are distributed at equal intervals, and a fixing through hole is formed in the middle of each fixing block 24.

As shown in fig. 21, the control system of the active fog ion generating device includes a control module 4 in communication connection with a main system, and an identity unit, a wireless receiving unit and a control unit are arranged inside the control module 4;

the identity unit sets identity information data, and the identity information data carried by different identity units are different, and one control module has specific identity information data, so that a main system can conveniently retrieve the corresponding control module according to the identity information data;

the wireless receiving unit comprises a signal interface and an instruction interface, the signal interface is used for receiving a digital signal transmitted by a main system and synchronously feeding the digital signal back to the instruction interface, and the instruction interface is used for converting the digital signal into an instruction signal and transmitting the instruction signal to the control unit;

the control unit is a control chip which controls the piezoelectric ceramic piece 3, the electromagnetic valve 16 and the micro pump 17 according to the instruction signal, controls whether the equipment is atomized or not and the degree of atomization by controlling whether the piezoelectric ceramic piece 3 works or not and the magnitude of generated load voltage, controls the amount of liquid added into the water storage tank 5 by controlling the electromagnetic valve 16 and the micro pump 17, the circuit board 2 generates a current signal according to the instruction signal, the current signal is transmitted to the lower electrode plate 8 and the upper electrode plate 9 through the internal lead of the line pipe 31, and a high-voltage electric field is formed between the lower electrode plate 8 and the upper electrode plate 9;

the main system comprises a display unit and a plurality of wireless transmitting units, the display unit is mainly used for displaying working conditions of the fog ion generating devices corresponding to the control modules 4, the wireless transmitting units are respectively in communication connection with the corresponding wireless receiving units, and the main system controls the control modules 4 simultaneously so as to control the active fog ion generating devices.

In the actual use process, referring to fig. 1, firstly, the piezoelectric ceramic chip 3, the electromagnetic valve 16 and the micro pump 17 are connected with an external water source pipeline through a threaded pipe 20 and a connecting pipe 18, a main system searches a wireless transmitting unit corresponding to a wireless receiving unit of identity information according to the identity information of each device, the wireless receiving unit and the wireless transmitting unit are connected through bluetooth, the main system transmits a data instruction through the wireless transmitting unit, the wireless receiving unit of the control module 4 receives the data instruction through a signal interface and feeds the data instruction back to the instruction interface, the instruction interface is used for converting a digital signal into an instruction signal and transmitting the instruction signal to the control unit, the data instruction comprises a voltage coefficient, an electromagnetic valve 16 parameter and a micro pump 17 power coefficient, a control chip in the control unit obtains the data instruction and controls the piezoelectric ceramic chip 3, the electromagnetic valve 16 and the micro pump 17 to work according to the data instruction, during the working process, the micro pump 17 works, the micro pump 17 absorbs water, water flow is sucked from the connecting pipe 18, finally enters the water storage tank 5 through the water inlet pipe 6 and finally passes through the two corresponding groups of water outlets 15, the sponge 7 is shaped through a plurality of holes in the water storage tank 5, when the water storage tank 5 is full of water, the water flow overflows from the water holes 11 of the lower electrode plate 8 and reaches the water storage groove 10, the piezoelectric ceramic plate 3 generates ultrasonic waves at the moment, the ultrasonic waves oscillate to atomize liquid moisture on the lower electrode plate 8 and generate active fog ions, current is generated by the circuit board 2, a high-voltage electric field is generated between the upper electrode plate 9 and the lower electrode plate through a lead of the line pipe 31, the electrolytic cones 12 electrolyze to generate active fog ions carrying charges, the active fog ions move upwards under the action of the electric field force, because the inverted fog inlet funnel 14 is arranged right above each electrolytic cone 12 arranged in the array, active mist ions enter the thin tube 13 through the inverted mist inlet funnel 14, pass through the upper electrode plate 9 and then enter the mist outlet channel, the mist outlet channel 21 with the inclined side wall pressurizes the active mist ions to improve the spraying speed of the active mist ions, the active mist ions reach the mist outlet tube 22, the direction of the steering assembly is adjusted through the fixing block 24 and the L-shaped fixing leg 26 according to the direction requirement, the air blower 28 is started, the air flow rate of the air blower 28 is increased from one side of the bent tube 27, the active mist ions enter the bent tube 27 and then are subjected to siphonage phenomenon generated in the bent tube 27 through the air blower 28, the spraying speed of the active mist ions is increased again, and finally the active mist ions are sprayed out from the second filter screen.

Example two

Fig. 16 is a schematic diagram of an overall structure of an active mist ion generating device according to a second embodiment of the present invention, please refer to fig. 6-15 and fig. 17-19, the active mist ion generating device and a control system thereof according to the present embodiment includes a device body, the device body includes an atomizing assembly, a water storage assembly and a mist outlet assembly;

the atomization assembly comprises a substrate 1, a circuit board 2 arranged on the substrate 1, a piezoelectric ceramic piece 3 arranged on the upper part of the circuit board 2 and a control module 4;

the fog outlet assembly comprises a lower electrode plate 8 arranged on the upper portion of a water storage tank 5, an upper electrode plate 9 arranged above the lower electrode plate 8, the lower electrode plate 8 corresponds to the upper electrode plate 9, circular water storage grooves 10 are formed in the upper portion of the lower electrode plate 8, a plurality of water storage grooves 10 are distributed in an array mode, a water hole 11 is formed in the bottom of each water storage groove 10, an electrolytic cone 12 is arranged between every two adjacent water storage grooves 10, fine pipes 13 are arranged on the upper electrode plate 9 in a penetrating mode, the fine pipes 13 are distributed in an array mode, a fog inlet funnel 14 is connected to the end of each fine pipe 13 in a penetrating mode, the diameter of the upper end of each fog inlet funnel 14 is the same as the diameter of each fine pipe 13, the diameter of the lower end of each fog inlet funnel 14 is larger than the diameter of the upper end of each fog inlet funnel, the side walls of every two fog inlet funnels 14 are tightly attached to each other, each fog inlet funnel 14 in the array mode is located right above the corresponding to the electrolytic cones 12 in the array mode.

In this embodiment, one end of the water inlet pipe 6 is provided with a plurality of water outlets 15, the other end of the water inlet pipe 6 is provided with an electromagnetic valve 16, the plurality of water outlets 15 are divided into two groups, the two groups of the plurality of water outlets 15 are symmetrically distributed about the central axis of the water storage tank 5, one end of each water outlet 15 is communicated with the water storage tank 5, and the plurality of water outlets 15 on the two sides are convenient for adding water into the water storage tank 5.

In this embodiment, the lateral wall of the substrate 1 is provided with the micro pump 17, the micro pump 17 is provided with a water inlet and a water outlet, the water outlet of the micro pump 17 is connected with the lower end of the water inlet pipe 6, the water inlet of the micro pump 17 is connected with the connecting pipe 18, the lower end of the connecting pipe 18 is provided with the sealing ring 19 and the threaded pipe 20, and the micro pump 17 is mainly used for adding water into the water storage tank 5.

In this embodiment, the device body further includes a nozzle assembly, the nozzle assembly includes a mist outlet channel 21 and a mist outlet pipe 22, the mist outlet channel 21 is of a step structure, the interior of the mist outlet channel is hollow, the cross section of the lower opening of the mist outlet channel is of a square ring structure, the cross section of the upper opening of the mist outlet channel is of a circular ring structure, the lower end of the mist outlet channel 21 is connected with the upper surface of the upper electrode plate 9, the length of the lower end of the mist outlet channel 21 is the same as that of the upper electrode plate 9, the lower end of the mist outlet pipe 22 is connected with the surface of the mist outlet channel 21, the diameter of the inner wall and the outer wall of the mist outlet pipe 22 is the same as that of the upper opening of the mist outlet channel 21, the top end of the mist outlet pipe 22 is provided with a first filter screen 23, a bar-shaped through hole is formed in the middle of the first filter screen 23, the corner of the lower end of the bar-shaped through hole is processed in an arc, and the mist outlet channel 21 with an inclined inner wall is convenient for improving the active mist ion injection rate.

Wherein, go out the fog pipe 22 lateral wall and be equipped with a plurality of fixed blocks 24, a plurality of fixed blocks 24 are equidistant to be distributed, and fixing hole has been seted up at every fixed block 24 middle part, and the main effect of fixed block 24 and fixing hole is the fixed subassembly that turns to of being convenient for.

the identity units carry identity information data containing the control module 4, and the identity information data carried by different identity units are the same;

In the actual use process, referring to fig. 16, firstly, the piezoelectric ceramic chip 3, the electromagnetic valve 16 and the micro pump 17 are connected with an external water source pipeline through a threaded pipe 20 and a connecting pipe 18, a main system searches a wireless transmitting unit corresponding to the identity information wireless receiving unit according to identity information of each device, the wireless receiving unit and the wireless transmitting unit are connected through bluetooth, the main system transmits a data instruction through the wireless transmitting unit, the wireless receiving unit of the control module 4 receives the data instruction through a signal interface and feeds the data instruction back to the instruction interface, the instruction interface is used for converting a digital signal into an instruction signal and transmitting the instruction signal to the control unit, the data instruction comprises a voltage coefficient, an electromagnetic valve 16 parameter and a micro pump 17 power coefficient, a control chip in the control unit obtains the data instruction and controls the piezoelectric ceramic chip 3, the electromagnetic valve 16 and the micro pump 17 to work according to the data instruction, during the working process, the micro pump 17 works, the micro pump 17 absorbs water, water flow is sucked from the connecting pipe 18, finally enters the water storage tank 5 through the water inlet pipe 6 and the two corresponding groups of water outlets 15, the sponge 7 is shaped through a plurality of holes in the water storage tank 5, when the water storage tank 5 is full of water, the water flow overflows from the water holes 11 of the lower electrode plate 8, the water flow reaches the water storage groove 10, the piezoelectric ceramic plate 3 generates ultrasonic waves at the moment, the ultrasonic waves oscillate to atomize liquid moisture on the lower electrode plate 8 to generate active molecules, current is generated through the circuit board 2, a high-voltage electric field is generated between the upper electrode plate 9 and the lower electrode plate through a lead of the line pipe 31, the electrolytic cones 12 electrolyze to generate active fog ions carrying charges, the active fog ions move upwards under the action of the electric field force, because the inverted fog inlet funnel 14 is arranged right above each electrolytic cone 12 arranged in the array, the active fog ions enter the thin pipes 13 through the inverted fog inlet funnels 14, after passing through the upper electrode plate 9, the active mist ions enter the mist outlet channel, the mist outlet channel 21 with the inclined side wall pressurizes the active mist ions, the spraying speed of the active mist ions is improved, and the active mist ions reach the mist outlet pipe 22 and are sprayed out from the first filter screen 23 at the top end of the mist outlet pipe 22.

EXAMPLE III

Fig. 20 is a schematic view of the overall structure of an active mist ion generating device according to a third embodiment of the present invention, and referring to fig. 6 to 15 and fig. 17 to 19, an active mist ion generating device according to a third embodiment of the present invention includes a device body, the device body includes an atomizing assembly, a water storage assembly, a mist outlet assembly, and a water tank 32;

a liquid outlet pipe 33 is arranged at the bottom of the water tank 32, a nut ring 34 is arranged at the upper end of the connecting pipe 18, the nut ring 34 is matched with the threaded pipe 20, the threaded pipe 20 is in threaded connection, the upper wall of the nut ring 34 is tightly attached to the sealing ring 19 to seal the liquid outlet pipe 33 and the water tank 32, a bottle mouth 35 is arranged at the upper part of the water tank 32 in a penetrating way, and a bottle cap 36 is in threaded connection with the bottle mouth 35;

As shown in fig. 21, the control system of the active fog ion generating device includes a control module 4 in communication connection with the main system, and an identity unit, a wireless receiving unit and a control unit are arranged inside the control module 4;

In the actual use process, referring to fig. 20, firstly, the threaded pipe 20 is in threaded connection with the nut ring 34, the bottle cap 36 is opened, liquid is added into the water tank 32 from the bottle opening 35, the main system searches the wireless transmitting unit corresponding to the wireless receiving unit of the identity information according to the identity information of each device, the wireless receiving unit is connected with the wireless transmitting unit through the bluetooth, the main system transmits a data instruction through the wireless transmitting unit, the wireless receiving unit of the control module 4 receives the data instruction through the signal interface and feeds the data instruction back to the instruction interface, the instruction interface is used for converting a digital signal into an instruction signal and transmitting the instruction signal to the control unit, the data instruction comprises a voltage coefficient, an electromagnetic valve 16 parameter and a micro-pump 17 power coefficient, the control chip in the control unit acquires the data instruction, and the piezoelectric 3, the ceramic chip, the micro-pump 17 and the micro-ceramic chip are controlled according to the data instruction, The electromagnetic valve 16 and the micropump 17 work, the micropump 17 works in the working process, the micropump 17 absorbs water, water flow is absorbed from the connecting pipe 18, finally passes through the water inlet pipe 6 and enters the water storage tank 5 through the two corresponding groups of water outlets 15, the sponge 7 is shaped through a plurality of holes in the water storage tank 5, when the water storage tank 5 is full of water, the water flow overflows from the water holes 11 of the lower electrode plate 8 and reaches the water storage groove 10, at the moment, the piezoelectric ceramic plate 3 generates ultrasonic waves, the ultrasonic waves oscillate to atomize the liquid moisture on the lower electrode plate 8 and generate active molecules, a current is generated by the circuit board 2, a high-voltage electric field is generated between the upper electrode plate 9 and the lower electrode plate through a lead of the wire pipe 31, the electrolytic cones 12 electrolyze to generate active fog ions carrying electric charges, the active fog ions move upwards under the action of the electric field, and because an inverted fog inlet funnel 14 is arranged right above each electrolytic cone 12 arranged in the array, active mist ions enter the thin tube 13 through the inverted mist inlet funnel 14, pass through the upper electrode plate 9 and then enter the mist outlet channel, the mist outlet channel 21 with the inclined side wall pressurizes the active mist ions, the spraying speed of the active mist ions is improved, and the active mist ions reach the mist outlet tube 22 and are sprayed out from the first filter screen 23 at the top end of the mist outlet tube 22.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an active fog ion generator, includes the device body, its characterized in that: the device body comprises an atomizing component, a water storage component and a mist outlet component;

the atomization assembly comprises a substrate (1), a circuit board (2) arranged on the substrate (1), a piezoelectric ceramic piece (3) arranged on the upper part of the circuit board (2) and a control module (4);

the water storage assembly comprises a water storage tank (5) arranged above the base plate (1), a water inlet pipe (6) arranged on the side wall of the water storage tank (5) and a shaping sponge (7) arranged inside the water storage tank (5);

the fog outlet assembly comprises a lower electrode plate (8) arranged on the upper part of a water storage tank (5), an upper electrode plate (9) arranged on the upper part of the lower electrode plate (8), the lower electrode plate (8) and the upper electrode plate (9) correspond to each other, a circular water storage groove (10) is arranged on the upper part of the lower electrode plate (8), a plurality of water storage grooves (10) are distributed in an array manner, every water storage groove (10) is provided with a water hole (11) at the bottom and is adjacent to the water storage groove (10) between which an electrolytic cone (12) is arranged, a thin tube (13) is arranged on the upper electrode plate (9) in a run-through manner, a plurality of thin tubes (13) are distributed in an array manner, every thin tube (13) end is connected with a fog inlet funnel (14) in a run-through manner, the upper end diameter of the fog inlet funnel (14) is the same as the diameter of the thin tube (13), the lower end diameter of the fog inlet funnel (14) is larger than the upper end diameter thereof, and every two fog inlet funnels (14) are tightly attached to each other, each fog inlet funnel (14) is positioned right above the electrolytic cone (12), and the fog inlet funnels (14) distributed in an array correspond to the electrolytic cones (12) distributed in the array one to one.

2. The active mist ion generating device of claim 1, wherein: go out fog subassembly still establishes cage (30) at last electrode board (9) and lower electrode board (8) outer wall including the cover, cage (30) lateral wall is equipped with spool (31), spool (31) lower extreme is connected with base plate (1), spool (31) upper end is passed cage (30) and is connected with last electrode board (9) lateral wall, spool (31) middle part protruding pipe pass cage (30) with lower electrode board (8) lateral wall is connected.

3. The active mist ion generating device of claim 2, wherein: the improved water storage tank is characterized in that one end of the water inlet pipe (6) is provided with a plurality of water outlet heads (15), the other end of the water inlet pipe (6) is provided with an electromagnetic valve (16), the water outlet heads (15) are divided into two groups, the two groups of water outlet heads (15) are respectively symmetrically distributed about the central axis of the water storage tank (5), and each water outlet head (15) is communicated with the water storage tank (5).

4. The active mist ion generating device of claim 3, wherein: base plate (1) lateral wall is equipped with micropump (17), micropump (17) are equipped with water inlet and delivery port, micropump (17) delivery port with inlet tube (6) lower extreme is connected, micropump (17) water inlet is connected with connecting pipe (18), connecting pipe (18) lower extreme is equipped with sealing washer (19) and screwed pipe (20).

5. The active mist ion generating device of claim 4, wherein: the device body further comprises a nozzle assembly, the nozzle assembly comprises a mist outlet channel (21) and a mist outlet pipe (22), the mist outlet channel (21) is of a step structure, the inner portion of the mist outlet channel is hollow, the cross section of a lower opening of the mist outlet channel is of a square ring structure, the cross section of an upper opening of the mist outlet channel is of a circular ring structure, the lower end of the mist outlet channel (21) is connected with the upper surface of an upper electrode plate (9), the side length of the lower end of the mist outlet channel (21) is the same as that of the upper electrode plate (9), the lower end of the mist outlet pipe (22) is connected with the surface of the mist outlet channel (21), the diameter of the inner wall and the outer wall of the mist outlet pipe (22) is the same as that of the inner wall and the outer wall of the upper opening of the mist outlet channel (21), a first filter screen (23) is arranged at the top end of the mist outlet pipe (22), a bar-shaped through hole is formed in the middle of the first filter screen (23), and the corner of the bar-shaped through hole is processed in an arc shape.

6. The active mist ion generating device of claim 5, wherein: the side wall of the mist outlet pipe (22) is provided with a plurality of fixing blocks (24), the fixing blocks (24) are distributed at equal intervals, and a fixing through hole is formed in the middle of each fixing block (24).

7. The active mist ion generating device of claim 6, wherein: the device body still includes and turns to the subassembly, turn to the subassembly and establish rotation tube (25) on fog play pipe (22) upper portion including the cover, rotation tube (25) lower extreme is equipped with a plurality of L shape fixed legs (26), L shape fixed leg (26) equidistant distribution, and with the mutual adaptation of fixed through hole, rotation tube (25) inner wall is equipped with the leather plug, the leather plug with go out fog pipe (22) outer wall and closely laminate.

8. The active mist ion generating device of claim 7, wherein: the upper end of the rotating pipe (25) is connected with an elbow pipe (27) in a penetrating way, one end of the elbow pipe (27) is provided with an air blower (28), and the other end of the elbow pipe (27) is used as an outlet end and is provided with a second filter screen (29).

9. A control system for an active mist ion generating device according to claim 8, comprising a control module (4) communicatively connected to the main system, characterized in that: an identity unit, a wireless receiving unit and a control unit are arranged in the control module (4);

identity information data are set in the identity units, and the identity information data carried by different identity units are different;

the control unit is control chip, control chip controls piezoceramics piece (3), solenoid valve (16) and micropump (17) according to instruction signal, whether work and produce load voltage's big or small controlling means atomizes and the degree of atomization size through control piezoceramics piece (3), add the inside liquid amount of aqua storage tank (5) through control solenoid valve (16) and micropump (17) control, circuit board (2) produce current signal according to instruction signal, current signal transmits to bottom plate electrode (8) and last electrode plate (9) through spool (31) inside wire, form high-tension electric field between bottom plate electrode (8) and last electrode plate (9).