CN114413372A

CN114413372A - High-pressure fog spraying type humidifier based on Internet of things

Info

Publication number: CN114413372A
Application number: CN202111554330.1A
Authority: CN
Inventors: 黄文利; 胡荣军
Original assignee: Anhui Jingyihong Environmental Technology Co ltd
Current assignee: Anhui Jingyihong Environmental Technology Co ltd
Priority date: 2021-12-17
Filing date: 2021-12-17
Publication date: 2022-04-29
Anticipated expiration: 2041-12-17
Also published as: CN114413372B

Abstract

The invention provides a high-pressure fog spraying type humidifier based on the Internet of things, which comprises a main body box, wherein one end of the interior of the main body box is provided with a sealing assembly, the other end of the interior of the main body box is provided with a high-pressure water pump, the output end of the high-pressure water pump is connected with a filtering assembly, and the output end of the filtering assembly is connected with an atomizing assembly; the sealing assembly comprises a sealing door rotationally connected with the main box through a hinge, a heat dissipation mechanism arranged on one side surface of the sealing door, and a sealing frame arranged on the inner wall surface of the main box, and an air outlet mechanism is arranged inside the sealing frame; the filtering component comprises a water inlet conical barrel connected with the output end of the high-pressure water pump and a filtering conical barrel arranged inside the water inlet conical barrel. The invention can reduce the clearance between the sealing door and the main box after the sealing door is closed, thereby reducing the erosion of external dust to the internal elements of the main box and reducing the pollution to the water source to be atomized.

Description

High-pressure fog spraying type humidifier based on Internet of things

Technical Field

The invention mainly relates to the technical field of humidifiers, in particular to a high-pressure fog-spraying humidifier based on the Internet of things.

Background

The Internet of things can be used for connecting any object with a network through information sensing equipment according to an agreed protocol, the object carries out information exchange and communication through an information transmission medium, and at present, the Internet of things is often used for controlling a high-pressure spray type humidifier so as to realize an intelligent supervision function.

According to the retractable auto-induction humidifier provided by the patent document with the application number of CN201911383679.6, the humidifier comprises a main body box fixedly connected with a ceiling, a rotary transmission chamber is arranged in the main body box, a first driven shaft which extends upwards into the rotary transmission chamber and downwards to the outside is connected to the lower end wall of the rotary transmission chamber in a rotary fit manner, a rotary box is fixedly connected to the bottom end face of the first driven shaft, a sliding box chamber with an outward opening is arranged in the rotary box, a first water pipe which penetrates up and down and extends downwards into the sliding box chamber is arranged in the first driven shaft, the telescopic auto-induction humidifier can be applied to rooms with different diameters by adjusting the position of the sliding box, the rotary box can sense the dry part of the room at the first time and switch the meshing state, the spraying is completed by the combined action of the piston movement and the atomizing nozzle, so that the dry part can be rapidly recovered to the conventional humidity, after humidification is finished, spraying is stopped, and the rotating box continues to rotate, so that overhigh humidity in a room caused by excessive humidification is prevented.

The atomizer completes atomization through the combined action of the piston movement and the atomizing nozzle, so that the dry part can be rapidly recovered to the conventional humidity, but after the traditional humidifier is used for a period of time, dust in the humidifier easily pollutes the traditional humidifier, and the cleanliness of atomized gas is easily influenced, so that the working environment is further influenced.

Disclosure of Invention

The invention mainly provides a high-pressure spray humidifier based on the Internet of things, which is used for solving the technical problems in the background technology.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the high-pressure fog-spraying humidifier based on the Internet of things comprises a main body box, wherein one end of the interior of the main body box is provided with a sealing assembly, the other end of the interior of the main body box is provided with a high-pressure water pump, the output end of the high-pressure water pump is connected with a filtering assembly, and the output end of the filtering assembly is connected with an atomizing assembly;

the sealing assembly comprises a sealing door rotationally connected with the main box through a hinge, a heat dissipation mechanism arranged on one side surface of the sealing door, and a sealing frame which is arranged on the inner wall surface of the main box and is used for the heat dissipation mechanism to penetrate through, wherein an air outlet mechanism is arranged inside the sealing frame;

the filter assembly comprises a water inlet conical barrel connected with the output end of the high-pressure water pump and a filter conical barrel arranged in the water inlet conical barrel, a drain pipe is arranged at the bottom end of the water inlet conical barrel, a water outlet pipe is arranged at the bottom end of the filter conical barrel, and the water outlet pipe penetrates through the water inlet conical barrel and extends to the outside to be connected with the water inlet end of the atomization assembly;

the filter assembly further comprises a negative pressure air suction mechanism arranged inside the main box, the air inlet end of the negative pressure air suction mechanism is connected with the air outlet mechanism, and the air outlet end of the negative pressure air suction mechanism is connected with the filtering cone.

Furthermore, the heat dissipation mechanism comprises a sealing plate arranged on one side surface of the sealing door and a heat dissipation fan arranged on one side surface of the sealing door far away from the sealing door, when the sealing door is closed, the sealing door drives the sealing plate to be inserted into the sealing frame, so that the gap between the sealing door and the sealing frame is further reduced, and external dust is prevented from entering the main box along the gap.

Furthermore, the heat dissipation mechanism also comprises sealing strips arranged on the outer surface of the sealing plate and the inner surface of the sealing frame, and the sealing frame and the sealing plate are in mutual clearance through the sealing strips on the sealing frame and the sealing plate, so that external dust is further prevented from entering the main box along the clearance and polluting elements inside the main box.

Furthermore, the mechanism of giving vent to anger including the embedding in the inside ring of giving vent to anger of sealed frame, install in the outlet duct of giving vent to anger ring bottom to and the equidistance install in the head of giving vent to anger of the internal surface of ring, it runs through the sealing strip and extends to the outside to go out the head, and the air between sealing door and the sealed frame gets into out the gas ring along going out the gas head to finally get into out the gas head through giving vent to anger the ring.

Further, the negative pressure air suction mechanism comprises a vacuum pump arranged on the surface of the inner wall of the bottom end of the main box body, an air suction pipe connected with the air inlet end of the vacuum pump, and an exhaust pipe connected with the air outlet end of the vacuum pump, wherein one end of the air suction pipe, which is far away from the vacuum pump, is connected with one end, which extends to the outside, of the air outlet pipe, one end, which is far away from the vacuum pump, of the exhaust pipe extends to the inside of the filtering cone, air entering the vacuum pump enters the filtering cone through the exhaust pipe under the action of the vacuum pump, and therefore when the filtering cone is blocked, the pressure difference between the inner side of the filter screen of the filtering cone and the outer side of the filter screen is caused.

Furthermore, a controller is installed at the top end of the main body box, and a high-pressure water pump and a vacuum pump which are connected with the controller through wires are controlled through the controller.

Furthermore, the sealing assembly further comprises a magnet arranged on the surface of one side of the sealing door and a reed pipe arranged at the top end of the sealing frame, the input end of the reed pipe is connected with the controller through a lead, and the output end of the reed pipe is connected with the vacuum pump through a lead.

Further, the atomization component include with the atomizing heater that the outlet pipe is connected, and with the atomizer that atomizing heater's output is connected, the atomizer runs through main part case extends to the outside, heats the rivers that the outlet pipe flows through atomizing heater to make this rivers atomizing, so that subsequent atomizer is atomized.

Further, atomizing heater including install in the inside heat preservation shell of main part incasement portion wears to locate the inside heating rod of heat preservation shell, and wear to locate the inside raceway of heating rod, the input of raceway with the outlet pipe is connected, the output with the atomizer is connected, heats the inside rivers of raceway through the heating rod, keeps warm through the asbestos between heat preservation shell and the heating rod.

Furthermore, the upper surface mounting of heat preservation shell has temperature detect switch, temperature detect switch through the wire with the heating rod is connected, adjusts the limit temperature that the heating rod can export through temperature detect switch to protect the heating rod.

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

firstly, the invention can reduce the clearance between the sealing door and the main box after the sealing door is closed, thereby reducing the erosion of external dust to the internal elements of the main box, and specifically comprises the following steps: the air between the sealing door and the sealing frame sequentially enters the air outlet ring and the air outlet head along the air outlet head, and the air enters the air suction pipe of the vacuum pump through the air outlet head.

Secondly, the invention can filter the water flow output by the high-pressure water pump, and can clean the filtering cone cylinder after the sealing door is closed, thereby reducing pollution, and the invention specifically comprises the following steps: the air that gets into the vacuum pump under the effect of vacuum pump, gets into through the blast pipe and filters a cone to when filtering the jam of a cone, cause the pressure differential that filters the filter screen inboard and the filter screen outside of a cone, so that the impurity of attaching to on filtering a cone falls to filtering in the clearance between a cone and the water inlet cone with the help of this pressure differential.

The present invention will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

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

FIG. 2 is a schematic view showing the internal structure of the main body case of the present invention;

FIG. 3 is a top view of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is an enlarged view of the structure of area A in FIG. 4;

FIG. 6 is a schematic structural view of the seal assembly of the present invention;

FIG. 7 is a schematic view of the structure of the main body case of the present invention;

fig. 8 is a schematic diagram of the filter assembly and atomization assembly of the present invention.

In the figure: 10. a main body case; 20. a seal assembly; 21. a sealing door; 22. a heat dissipation mechanism; 221. a sealing plate; 222. a heat radiation fan; 223. a sealing strip; 23. a sealing frame; 24. an air outlet mechanism; 241. an air outlet ring; 242. an air outlet head; 243. an air outlet pipe; 25. a magnet; 26. a reed switch; 30. a high pressure water pump; 40. a filter assembly; 41. a water inlet cone; 42. a filter cone; 43. a water outlet pipe; 44. a negative pressure suction mechanism; 441. a vacuum pump; 442. an air intake duct; 443. an exhaust pipe; 45. a blow-off pipe; 50. an atomizing assembly; 51. an atomizing heater; 511. a heat preservation shell; 5111. a temperature control switch; 512. a heating rod; 513. a water delivery pipe; 52. an atomizer.

Detailed Description

In order to facilitate an understanding of the invention, the invention will now be described more fully hereinafter with reference to the accompanying drawings, in which several embodiments of the invention are shown, but which may be embodied in different forms and not limited to the embodiments described herein, but which are provided so as to provide a more thorough and complete disclosure of the invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present, as the terms "vertical", "horizontal", "left", "right" and the like are used herein for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the knowledge of the terms used herein in the specification of the present invention is for the purpose of describing particular embodiments and is not intended to limit the present invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

In an embodiment, referring to fig. 1 to 8, a high-pressure mist spray humidifier based on the internet of things includes a main body box 10, one end of the interior of the main body box 10 is provided with a sealing assembly 20, the other end of the interior of the main body box is provided with a high-pressure water pump 30, an output end of the high-pressure water pump 30 is connected with a filtering assembly 40, and an output end of the filtering assembly 40 is connected with an atomizing assembly 50;

the sealing assembly 20 comprises a sealing door 21 rotatably connected with the main body box 10 through a hinge, a heat dissipation mechanism 22 arranged on the surface of one side of the sealing door 21, and a sealing frame 23 which is arranged on the surface of the inner wall of the main body box 10 and is used for the heat dissipation mechanism 22 to penetrate through, wherein an air outlet mechanism 24 is arranged inside the sealing frame 23;

the filter assembly 40 comprises a water inlet cone cylinder 41 connected with the output end of the high-pressure water pump 30 and a filter cone cylinder 42 arranged inside the water inlet cone cylinder 41, a sewage discharge pipe 45 is arranged at the bottom end of the water inlet cone cylinder 41, a water outlet pipe 43 is arranged at the bottom end of the filter cone cylinder 42, and the water outlet pipe 43 penetrates through the water inlet cone cylinder 41 and extends to the outside to be connected with the water inlet end of the atomization assembly 50;

the filtering assembly 40 further includes a negative pressure suction mechanism 44 disposed inside the main body box 10, an air inlet end of the negative pressure suction mechanism 44 is connected to the air outlet mechanism 24, and an air outlet end is connected to the filtering cone 42.

Specifically, please refer to fig. 2 and 6 again, the heat dissipation mechanism 22 includes a sealing plate 221 installed on a side surface of the sealing door 21, a heat dissipation fan 222 installed on a side surface of the sealing plate 221 away from the sealing door 21, and a sealing strip 223 installed on an outer surface of the sealing plate 221 and an inner surface of the sealing frame 23;

it should be noted that, in the embodiment, when the sealing door 21 is closed, the sealing door 21 drives the sealing plate 221 to be inserted into the sealing frame 23, so as to further reduce the gap between the sealing door 21 and the sealing frame 23, and prevent external dust from entering the main body box 10 along the gap and polluting elements inside the main body box 10;

further, the sealing frame 23 and the sealing plate 221 are spaced apart from each other by the sealing strips 223 thereon, so that external dust is further prevented from entering the main body case 10 through the gap and contaminating the components inside the main body case 10.

Specifically, please refer to fig. 2 and 6 again, the air outlet mechanism 24 includes an air outlet ring 241 embedded inside the sealing frame 23, an air outlet pipe 243 installed at the bottom end of the air outlet ring 241, and an air outlet head 242 equidistantly installed on the inner surface of the air outlet ring 241, the air outlet head 242 extends to the outside through the sealing strip 223, the negative pressure air suction mechanism 44 includes a vacuum pump 441 installed on the inner wall surface of the bottom end of the main body box 10, an air suction pipe 442 connected to the air inlet end of the vacuum pump 441, and an air outlet pipe 443 connected to the air outlet end of the vacuum pump 441, one end of the air suction pipe 442 away from the vacuum pump 441 is connected to one end of the air outlet pipe 243 extending to the outside, and one end of the air outlet pipe 443 away from the vacuum pump 441 extends to the inside of the filtering cone 42;

in the embodiment, after the sealing door 21 is closed, under the action of the vacuum pump 441, the air between the sealing door 21 and the sealing frame 23 enters the air outlet ring 241 along the air outlet head 242, and finally enters the air outlet head 242 through the air outlet ring 241;

further, the air between the sealing door 21 and the sealing frame 23 enters the air outlet ring 241 along the air outlet head 242, and finally enters the air outlet head 242 through the air outlet ring 241, the air enters the air suction pipe 442 of the vacuum pump 441 through the air outlet head 242, and finally enters the vacuum pump 441, the air entering the vacuum pump 441 enters the filtering cone 42 through the air exhaust pipe 443 under the action of the vacuum pump 441, so that when the filtering cone 42 is blocked, a pressure difference between the inner side and the outer side of the filter screen of the filtering cone 42 is generated, so that the impurities attached to the filtering cone 42 fall into a gap between the filtering cone 42 and the water inlet cone 41 by the pressure difference.

Specifically, please refer to fig. 2 and 7 again, a controller 11 is installed at the top end of the main body box 10, the sealing assembly 20 further includes a magnet 25 installed on a surface of one side of the sealing door 21, and a reed pipe 26 installed at the top end of the sealing frame 23, an input end of the reed pipe 26 is connected to the controller 11 through a wire, an output end of the reed pipe 26 is connected to the vacuum pump 441 through a wire, the atomizing assembly 50 includes an atomizing heater 51 connected to the water outlet pipe 43, and an atomizer 52 connected to an output end of the atomizing heater 51, the atomizer 52 extends to the outside through the main body box 10, the atomizing heater 51 includes a heat preservation shell 511 installed inside the main body box 10, a heating rod 512 penetrating inside the heat preservation shell 511, and a water pipe 513 penetrating inside the heating rod 512, an input end of the water pipe 513 is connected to the water outlet pipe 43, The output end of the temperature control switch 5111 is connected with the atomizer 52, the upper surface of the heat preservation shell 511 is provided with the temperature control switch 5111, and the temperature control switch 5111 is connected with the heating rod 512 through a lead;

note that, in the present embodiment, the high-pressure water pump 30 and the vacuum pump 441 connected to the controllers 11 through wires thereof are controlled;

further, after the sealing door 21 is closed, the magnet 25 on the sealing door 21 is close to the reed pipe 26, so that the reed pipe 26 is opened, the controller 11 can be connected with the vacuum pump 441 through a conducting wire, the vacuum pump 441 is controlled, and after the sealing door 21 is closed, a worker can control the vacuum pump 441 to remind the worker of the state of the sealing door 21 in this way, so that the sealing door 21 is ensured to be closed, and external dust is prevented from entering the main body box 10;

further, the water flow flowing out of the water outlet pipe 43 is heated by the atomizing heater 51 to atomize the water flow, so that the subsequent atomization by the atomizer 52 is facilitated, and the temperature of the water mist generated by the atomizer 52 can be adjusted;

further, the water flow in the water pipe 513 is heated through the heating rod 512, and heat is preserved through asbestos between the heat preservation shell 511 and the heating rod 512;

further, the limit temperature that the heating rod 512 can output is adjusted by the temperature control switch 5111, thereby protecting the heating rod 512.

The specific operation mode of the invention is as follows:

when the humidifier is used, after a worker pushes the sealing door 21 to be closed, water flow output by the high-pressure water pump 30 enters the water inlet cone cylinder 41, is filtered by the filter cone cylinder 42 in the water inlet cone cylinder 41, is discharged into the atomizing heater 51 through the water outlet pipe 43 to be heated and atomized, and is further atomized through the atomizer 52 and flows into a pipeline connected with the atomizer to be discharged through the pipeline to perform humidification work;

after the sealing door 21 is closed, the vacuum pump 441 starts to operate, air between the sealing door 21 and the sealing frame 23 enters the air outlet ring 241 along the air outlet head 242, and finally enters the air outlet head 242 through the air outlet ring 241, and the air enters the air suction pipe 442 of the vacuum pump 441 through the air outlet head 242, in the process, the sealing strips 223 between the sealing door 21 and the sealing frame 23 are close to each other by virtue of the vacuum environment, so that the gap between the sealing door 21 and the sealing frame 23 is reduced, and external dust is prevented from entering the main body box 10 along the gap to pollute elements inside the main body box 10;

the air introduced into the vacuum pump 441 enters the filter cone 42 through the exhaust pipe 443 by the vacuum pump 441, so that when the filter cone 42 is clogged, a pressure difference between the inside and the outside of the filter net of the filter cone 42 is generated, and the impurities attached to the filter cone 42 fall into the gap between the filter cone 42 and the water inlet cone 41 by the pressure difference.

The invention is described above with reference to the accompanying drawings, it is obvious that the invention is not limited to the above-described embodiments, and it is within the scope of the invention to adopt such insubstantial modifications of the inventive method concept and solution, or to apply the inventive concept and solution directly to other applications without modification.

Claims

1. The high-pressure fog-spraying humidifier based on the Internet of things comprises a main body box (10), and is characterized in that one end of the interior of the main body box (10) is provided with a sealing assembly (20), the other end of the interior of the main body box is provided with a high-pressure water pump (30), the output end of the high-pressure water pump (30) is connected with a filtering assembly (40), and the output end of the filtering assembly (40) is connected with an atomizing assembly (50);

the sealing assembly (20) comprises a sealing door (21) rotatably connected with the main box (10) through a hinge, a heat dissipation mechanism (22) arranged on the surface of one side of the sealing door (21), and a sealing frame (23) which is arranged on the surface of the inner wall of the main box (10) and is used for the heat dissipation mechanism (22) to penetrate through, wherein an air outlet mechanism (24) is arranged inside the sealing frame (23);

the filter assembly (40) comprises a water inlet conical cylinder (41) connected with the output end of the high-pressure water pump (30) and a filter conical cylinder (42) arranged inside the water inlet conical cylinder (41), a sewage discharge pipe (45) is arranged at the bottom end of the water inlet conical cylinder (41), a water outlet pipe (43) is arranged at the bottom end of the filter conical cylinder (42), and the water outlet pipe (43) penetrates through the water inlet conical cylinder (41) and extends to the outside to be connected with the water inlet end of the atomization assembly (50);

the filtering assembly (40) further comprises a negative pressure air suction mechanism (44) arranged inside the main body box (10), the air inlet end of the negative pressure air suction mechanism (44) is connected with the air outlet mechanism (24), and the air outlet end of the negative pressure air suction mechanism (44) is connected with the filtering cone (42).

2. The internet-of-things-based high-pressure mist spray humidifier according to claim 1, wherein the heat dissipation mechanism (22) comprises a sealing plate (221) mounted on one side surface of the sealing door (21), and a heat dissipation fan (222) mounted on one side surface of the sealing plate (221) far away from the sealing door (21).

3. The internet-of-things-based high-pressure mist humidifier according to claim 2, wherein the heat dissipation mechanism (22) further comprises a sealing strip (223) arranged on the outer surface of the sealing plate (221) and the inner surface of the sealing frame (23).

4. The high-pressure mist spray humidifier based on the internet of things of claim 3, wherein the air outlet mechanism (24) comprises an air outlet ring (241) embedded inside the sealing frame (23), an air outlet pipe (243) installed at the bottom end of the air outlet ring (241), and air outlet heads (242) installed at the inner surface of the air outlet ring (241) at equal intervals, and the air outlet heads (242) extend to the outside through a sealing strip (223).

5. The high pressure mist spray humidifier based on the internet of things as claimed in claim 4, wherein the negative pressure suction mechanism (44) comprises a vacuum pump (441) mounted on the inner wall surface of the bottom end of the main body case (10), a suction pipe (442) connected to the inlet end of the vacuum pump (441), and an exhaust pipe (443) connected to the outlet end of the vacuum pump (441), wherein one end of the suction pipe (442) far away from the vacuum pump (441) is connected to one end of the outlet pipe (243) extending to the outside, and one end of the exhaust pipe (443) far away from the vacuum pump (441) extends to the inside of the filter cone (42).

6. The Internet of things-based high-pressure mist spray humidifier according to claim 5, wherein a controller (11) is mounted at the top end of the main body case (10).

7. The high-pressure fog-spray humidifier based on the internet of things as claimed in claim 6, wherein the sealing assembly (20) further comprises a magnet (25) mounted on one side surface of the sealing door (21), and a reed switch (26) mounted on the top end of the sealing frame (23), wherein the input end of the reed switch (26) is connected with the controller (11) through a conducting wire, and the output end of the reed switch is connected with the vacuum pump (441) through a conducting wire.

8. The internet-of-things-based high-pressure mist humidifier according to claim 7, wherein the atomizing assembly (50) comprises an atomizing heater (51) connected with the water outlet pipe (43), and an atomizer (52) connected with an output end of the atomizing heater (51), wherein the atomizer (52) extends to the outside through the main body case (10).

9. The high-pressure mist spray humidifier based on the internet of things as claimed in claim 8, wherein the atomizing heater (51) comprises a heat preservation shell (511) installed inside the main body box (10), a heating rod (512) penetrating inside the heat preservation shell (511), and a water pipe (513) penetrating inside the heating rod (512), wherein an input end of the water pipe (513) is connected with the water outlet pipe (43), and an output end of the water pipe is connected with the atomizer (52).

10. The high-pressure fog spray humidifier based on the internet of things as claimed in claim 9, wherein a temperature control switch (5111) is mounted on the upper surface of the heat preservation shell (511), and the temperature control switch (5111) is connected with the heating rod (512) through a wire.