CN117212952B - High-efficient air sterilizer based on thing networking - Google Patents

Abstract

The invention relates to the field of air disinfectors, in particular to an efficient air disinfector based on the Internet of things. The technical problems of the invention are as follows: in places with dense people flow, the common sterilizer can only purify and sterilize a small area near the air sterilizer, and can also influence normal actions of people. The technical scheme of the invention is as follows: an efficient air sterilizer based on the Internet of things comprises a base, a piston shell, a sterilizing box and the like; the base is movably connected with a piston shell; the inner bottom of the base is fixedly connected with a plurality of disinfection boxes. According to the invention, the air sterilizer is combined with the seat for waiting people at a dense position, and the seat can be used for sterilizing and purifying the air, so that the people sitting on the air sterilizer can fully breathe the sterilized and purified air, and three sterilization and purification modes are provided, so that the air can be effectively sterilized under different situations.

Description

High-efficient air sterilizer based on thing networking

Technical Field

The invention relates to the field of air disinfectors, in particular to an efficient air disinfector based on the Internet of things.

Background

Current air sterilizer includes: an air sterilizer of physical factors, which kills or removes microorganisms in the air by using electrostatic adsorption and ultraviolet lamp methods, such as an electrostatic adsorption type air sterilizer, an ultraviolet air sterilizer, etc.; an air sterilizer for chemical factors, which kills microorganisms in air by using the generated chemical factors to achieve air sterilization, such as a carbon dioxide air sterilizer, an ozone air sterilizer, a hydrogen peroxide air sterilizer, a peroxyacetic acid air sterilizer and the like; other factors such as ion air sterilizer, photo catalyst air sterilizer, etc.

Above-mentioned air sterilizer is great to the influence of people's life and equipment to be suitable for in the intensive place of people's air current, can only purify disinfection to a small area near the air sterilizer, and set up the air sterilizer of ground connection formula in the intensive place of people's air current, can influence people's normal action, if set up in remote position, the people is not near the sterilizer, and the sterilizer is after purifying the air of environment most, and the talent can breathe the air after the disinfection, and the time that the air disinfection played is longer, and the effect that the sterilizer played is limited.

Disclosure of Invention

The technical problems of the invention are as follows:

in order to overcome the defect that a common sterilizer can only purify and sterilize a small area near an air sterilizer and can influence normal actions of people, if the common sterilizer is arranged at a remote position, the sterilizer has a limited effect, and the invention provides the high-efficiency air sterilizer based on the Internet of things.

The technical implementation scheme adopted by the invention is as follows:

an efficient air sterilizer based on the Internet of things comprises a base, a piston shell and a dustproof net; the base is movably connected with a piston shell; the inside of the base is hollowed out; a cushion is laid on the upper surface of the piston shell, and a pressure sensor is arranged on the piston shell; a plurality of rows of first air inlets are formed in the piston shell; a plurality of rows of exhaust ports are formed in the piston shell; the exhaust port is positioned above the first air inlet; the lower part of the piston shell is fixedly connected with a supporting seat; the supporting seat is contacted with the inner bottom of the base; the base is detachably connected with a plurality of dustproof nets; the device also comprises a disinfection box, an electric hydraulic cylinder, an ozone generator, an air pump, an air box, an ozone absorber, a fixed plate and a first pull rope; a plurality of disinfection boxes are fixedly connected at the inner bottom of the base; a plurality of electric hydraulic cylinders are arranged at the inner bottom of the base; all the electric hydraulic cylinders are positioned between two adjacent disinfection boxes; all the electric hydraulic cylinder telescopic parts are fixedly connected with the inner top of the piston shell together; an ozone generator is fixedly connected at the inner bottom of the base, and a one-way valve is arranged in the ozone generator guide pipe; the ozone generator is positioned between two adjacent electric hydraulic cylinders; a plurality of air pumps are respectively arranged in each disinfection box; two rows of second air inlets are respectively formed in one side of each disinfection box far away from the ozone generator, and the inner diameter of the second air inlet above is smaller than that of the second air inlet below; a row of second air inlets above are matched with the adjacent first air inlets; a sensor is arranged in the second air inlet; a first baffle is fixedly connected in each disinfection box; each first partition plate divides the internal space of a disinfection box into two cavities, and a converging cabin is arranged in each disinfection box far away from the ozone generator; two second clapboards are fixedly connected with the cavity of one side of each first clapboards, which is close to the ozone generator, respectively; every two second baffle plates are fixedly connected with the inner wall, close to the ozone generator, of the disinfection box; each air pump is positioned in a space surrounded by a corner of the disinfection box, the first partition plate and the second partition plate; the cavity between every two adjacent second clapboards is a disinfection cabin; the disinfection cabin is communicated with the ozone generator conduit; every two adjacent air inlets of the air pump are communicated with one confluence cabin together; the air outlets of every two adjacent air pumps are communicated with a disinfection cabin together; the upper part of each disinfection box is respectively communicated with an air box; each bellows is movably connected with an ozone absorber; the upper part of each ozone absorber is fixedly connected with a fixing plate; the upper part of each fixed plate is respectively connected with a plurality of first pull ropes; all the upper parts of the first pull ropes are fixedly connected with the inner top surface of the piston shell.

Furthermore, it is particularly preferable that the ozone generator further comprises an air duct and an ozone duct; each air outlet of the air pump is communicated with an air duct, and a one-way valve is arranged in the air duct; the air duct is positioned in the disinfection cabin; every two adjacent air guide pipes are contacted; each air duct is provided with a plurality of air outlets; the front part and the rear part of the ozone generator guide pipe are respectively communicated with two ozone pipes, and a one-way valve is arranged in each ozone pipe; the ozone pipe is positioned in the disinfection cabin; every two adjacent ozone pipes are contacted; each ozone pipe is provided with a plurality of air outlets.

Furthermore, it is particularly preferred that the air outlet of the air duct is open at its lower part and that the air outlets are arranged in two rows in a splayed manner.

In addition, it is particularly preferable that the air outlets of the ozone pipe are opened at the lower part thereof, and the air outlets are in two rows of splayed symmetry.

In addition, it is particularly preferable that the air duct is disposed in parallel with the adjacent ozone duct.

In addition, it is particularly preferable that the liquid collecting device further comprises an electric rotating plate, a condensing pipe, a guide strip and a liquid collecting box; the upper part of the piston shell is provided with a plurality of storage grooves; each accommodating groove is rotationally connected with an electric rotating plate; one side of each electric rotating plate facing the piston shell is provided with an air guide groove; a plurality of condensing pipes are respectively arranged in each air guide groove; the lower part of each electric rotating plate is provided with a plurality of drainage grooves; each drainage groove corresponds to an adjacent condensation pipe; the upper part of the base is connected with a plurality of guide bars; each guide strip is positioned below one drainage groove; the upper part of the inner side of the base is provided with a plurality of liquid collecting boxes; each liquid collecting box is arranged below one guide strip.

Furthermore, it is particularly preferred that a side guard is also included; the upper part of the piston shell is fixedly connected with a plurality of side guard plates; the lower parts of all the side guard plates are connected with the base in a sliding way; the front part and the rear part of each side guard plate are respectively provided with a bending part; each side guard plate is matched with one electric rotating plate and used for shielding a gap between the upper part of the base and the upper part of the piston shell; the front part and the rear part of each side guard plate are respectively provided with a hidden groove; each hidden groove is connected with an air guide pipe; the air guide pipe is aligned with the gap position between the piston shell and the electric rotating plate, and is communicated with the corresponding gap; a porous plate is fixedly connected in each air guide pipe.

Furthermore, it is particularly preferred that the bottom of the hidden groove is inclined downward.

Furthermore, it is particularly preferred that the perforated plates are inclined and are arranged hidden in the respective air guide duct.

In addition, it is particularly preferable that the device further comprises a sliding rod, a baffle plate, an elastic piece, a connecting rod and a second stay cord; the upper part of the inner side of the piston shell is fixedly connected with a plurality of sliding rods respectively; a plurality of baffle plates are respectively connected to the two adjacent slide bars in a sliding way; each baffle is fixedly connected with a plurality of elastic pieces; each sliding rod is fixedly connected with a corresponding elastic piece; the lower parts of the baffle plates on the same side are fixedly connected with a connecting rod together; each connecting rod is fixedly connected with two second pull ropes; all the second pull ropes are fixedly connected with the top of the disinfection box together; each baffle is matched with one exhaust port; the fixed position of the second pull rope and the disinfection box and the fixed position of the second pull rope and the connecting rod are not on the same horizontal line.

Advantageous effects

1. At the dense position of people's air sterilizer and cushion, when providing the seat rest for waiting people, can also disinfect and purify air for the people who sits above that fully breathe the disinfection and purification after the air, provide three kinds of disinfection purification modes simultaneously, can carry out effectual disinfection treatment to the air under the different circumstances again.

2. Through turning down the condenser pipe, not only the moisture condensation in the air after the disinfection is accomplished, avoid moisture to wet people's trouser legs, and can also avoid people's finger to grab on piston shell upper portion, if this sterilizer breaks down afterwards, the finger is pressed from both sides and is injured, electric rotating plate has blocked the gas vent after turning down, avoid the air after the disinfection, directly blow child's eye, cause eye uncomfortable sense, and be provided with the condenser pipe on the electric rotating plate, the condenser pipe also cools down to sterile air, the people who sits on the piston shell cooling of cooling down, can also breathe nice and cool nontoxic air.

3. Through the perforated plate setting to hidden downward sloping's form, effectively avoid people to with the cavity shutoff on the perforated plate to set up hidden groove lower part to downward sloping, make people will pack into hidden groove's debris, can not fully fix, even by the jam, also accessible increase ventilation power blows out debris from hidden inslot, has the thing networking to contact sanitation personnel to clear up debris again, simultaneously blows out downwards.

Drawings

Fig. 1 is a schematic diagram of the overall three-dimensional structure of a module of the high-efficiency air sterilizer based on the internet of things;

FIG. 2 is an exploded view of the base and corresponding parts of the piston housing of the high efficiency air sterilizer based on the Internet of things of the present invention;

fig. 3 is a schematic diagram of a piston housing perspective structure of the high-efficiency air sterilizer based on the internet of things of the invention;

FIG. 4 is a schematic diagram of the relative installation positions of a sterilizing box, an electro-hydraulic cylinder and an ozone generator of the high-efficiency air sterilizer based on the Internet of things;

fig. 5 is a top view of the internal structure of a sterilizing box of the high-efficiency air sterilizer based on the internet of things;

FIG. 6 is a schematic diagram of the air flow of a person sitting on a piston housing of the high efficiency air sterilizer based on the Internet of things of the present invention;

FIG. 7 is a top view of the mounting positions of an air duct and an ozone duct of the high-efficiency air sterilizer based on the Internet of things;

FIG. 8 is a bottom view of the air duct and the upper air outlet opening of the ozone duct of the high-efficiency air sterilizer based on the Internet of things of the present invention;

FIG. 9 is a schematic diagram of the mounting position of an electric rotating plate of the high-efficiency air sterilizer based on the Internet of things;

FIG. 10 is a schematic diagram of the installation position of a guide bar of the high-efficiency air sterilizer based on the Internet of things of the present invention;

FIG. 11 is a schematic diagram of the mounting position of a condensing tube of the high-efficiency air sterilizer based on the Internet of things of the present invention;

FIG. 12 is a schematic diagram of the mounting position of a side guard plate of the high-efficiency air sterilizer based on the Internet of things of the present invention;

FIG. 13 is a view showing the position of a hidden perforated plate of the high-efficiency air sterilizer based on the Internet of things of the present invention;

fig. 14 is a schematic diagram of a mounting position of a baffle of the high-efficiency air sterilizer based on the internet of things of the present invention;

fig. 15 is a diagram showing the cooperation of a baffle and an exhaust port of the high-efficiency air sterilizer based on the internet of things.

In the figure: the device comprises a 1-base, a 2-piston shell, a 3-dust screen, a 4-sterilizing box, a 5-electric hydraulic cylinder, a 6-ozone generator, a 7-air pump, an 8-bellows, a 9-ozone absorber, a 10-fixing plate, an 11-first pull rope, a 2001-exhaust port, a 2002-first air inlet, a 2003-supporting seat, a 2004-containing groove, a 4001-second air inlet, a 4002-first partition plate, a 4003-confluence cabin, a 4004-second partition plate, a 4005-sterilizing cabin, a 101-air guide pipe, a 102-ozone pipe, a 201-electric rotating plate, a 202-condensing pipe, a 203-guide strip, a 204-collecting box, a 20101-air guide groove, a 20102-drainage groove, a 301-side guard plate, a 30101-bending part, a 30102-hiding groove, a 30103-air guide pipe, a 30104-porous plate, a 401-slide bar, a 402-blocking piece, a 403-elastic piece, a 404-connecting rod and a 405-second pull rope.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

According to the figures 1-15, the high-efficiency air sterilizer based on the Internet of things comprises a base 1, a piston shell 2 and a dust screen 3; the base 1 is movably connected with a piston shell 2; the inside of the base 1 is hollowed out; a cushion is paved on the upper surface of the piston shell 2, and a pressure sensor is arranged on the piston shell 2; the piston shell 2 is provided with two rows of first air inlets 2002 which are distributed back and forth; two rows of exhaust ports 2001 which are distributed back and forth are arranged on the piston shell 2; the exhaust port 2001 is located above the first intake port 2002; a supporting seat 2003 is welded at the lower part of the piston shell 2; the supporting seat 2003 is contacted with the inner bottom of the base 1; two dustproof nets 3 distributed front and back are detachably connected to the base 1; the dustproof net 3 can be arranged to be in knob type clamping connection or buckle type fixed connection;

the device also comprises a disinfection box 4, an electric hydraulic cylinder 5, an ozone generator 6, an air pump 7, an air box 8, an ozone absorber 9, a fixing plate 10 and a first pull rope 11; two disinfection boxes 4 which are distributed front and back are welded at the inner bottom of the base 1; two electric hydraulic cylinders 5 distributed left and right are arranged at the inner bottom of the base 1; all the electro-hydraulic cylinders 5 are positioned between two adjacent disinfection boxes 4; all the telescopic parts of the electric hydraulic cylinders 5 are fixedly connected with the inner top of the piston shell 2; the inner bottom of the base 1 is connected with an ozone generator 6 by bolts, and a one-way valve is arranged in a conduit of the ozone generator 6; the ozone generator 6 is positioned between two adjacent electro-hydraulic cylinders 5; two air pumps 7 distributed left and right are respectively arranged in each disinfection box 4; two rows of second air inlets 4001 are respectively formed on one side of each disinfection box 4 far away from the ozone generator 6, and the inner diameter of the upper second air inlet 4001 is smaller than that of the lower second air inlet 4001; an upper row of second air inlets 4001 cooperates with adjacent first air inlets 2002; a sensor is arranged in the second air inlet 4001 and is used for monitoring the air flow of the second air inlet 4001; a first partition 4002 is welded in each sterilizing box 4; each first partition 4002 divides the inner space of one disinfection box 4 into a front cavity and a rear cavity, and a confluence cabin 4003 is arranged in each disinfection box 4 far away from the ozone generator 6; two second partition boards 4004 are welded in each cavity of one side of each first partition board 4002 close to the ozone generator 6; each two second partition boards 4004 are welded with the inner wall of the disinfection box 4 close to the ozone generator 6; each air pump 7 is positioned in a space surrounded by the corner of one disinfection box 4, the first partition 4002 and the second partition 4004; the cavity between every two adjacent second partition boards 4004 is a disinfection cabin 4005; the disinfection cabin 4005 is communicated with a conduit of the ozone generator 6; the air inlets of every two adjacent air pumps 7 are communicated with one confluence cabin 4003; the air outlets of every two adjacent air pumps 7 are communicated with one disinfection cabin 4005; the upper part of each disinfection box 4 is respectively communicated with a bellows 8; each bellows 8 is movably connected with an ozone absorber 9; the upper part of each ozone absorber 9 is connected with a fixing plate 10 through bolts; the upper part of each fixed plate 10 is respectively connected with two first stay ropes 11 which are distributed left and right; the upper parts of all the first pull ropes 11 are fixedly connected with the inner top surface of the piston shell 2.

The specific working principle of the invention is as follows:

as shown in fig. 1, the base 1, the piston housing 2 and the dust screen 3 are in an operating state when a person sits on the cushion of the piston housing 2:

the air sterilizer comprises a plurality of air sterilizer modules, wherein the air sterilizer modules are connected with each other, remote sensing control is uniformly carried out through the Internet of things, a cushion is arranged at the top of a piston shell 2, and the air sterilizer modules can be used for sterilizing and purifying air while providing seats for waiting people, so that people sitting on the air sterilizer modules can fully breathe sterilized and purified air.

When a person approaches and sits on the cushion of the piston shell 2, the pressure sensor receives signals, the two electric hydraulic cylinders 5 are started to slowly shrink, the piston shell 2 is synchronously driven to slowly move downwards, when the supporting seat 2003 contacts with the inner bottom surface of the base 1, the two electric hydraulic cylinders 5 are closed, the weight of the person is borne by the piston shell 2 and the supporting seat 2003 thereof, as shown in fig. 6, the air outlet 2001 is communicated with the second air inlet 4001 below, all the air pumps 7 are started, the air inlets of the air pumps 7 suck external air through the confluence cabin 4003, the second air inlet 4001 above, the first air inlet 2002 and the dust screen 3, flocculent dust and impurities in the air are intercepted through the dust screen 3, then after a period of time, when a large amount of dust is accumulated on the dust screen 3, the internet of things positions the corresponding sterilizer module, and then special cleaning staff is dispatched to clean or replace the dust screen 3.

As shown in fig. 5 and 11, the air pump 7 blows the sucked air into the disinfection cabin 4005, wherein tap water is preloaded in the disinfection cabin 4005, before the air is led into the disinfection cabin 4005, the ozone generator 6 starts to work and generates ozone, and the ozone is filled into the disinfection cabin 4005 to form ozone water, the outside air is blown into the ozone water in the disinfection cabin 4005, the outside air is disinfected and purified through the ozone water, as shown in fig. 6, and then the air is discharged from the upper part of the disinfection box 4 and enters the bellows 8, the bellows 8 discharges the disinfected air outwards through the air outlet 2001, the ozone mixed in the air is absorbed, and the rest air is discharged outwards through the air outlet 2001, the people sitting on the piston housing 2 feel the wind blown out by the air outlet 2001, the dryness heat sensation of the people is relieved in the waiting process, and meanwhile, the people sitting on the piston housing 2 breathe the disinfected air more effectively through the air circulation treatment around the device, and a better disinfection effect is achieved.

When someone is around the present air sterilizer module, but not sitting on the piston housing 2:

on the basis of the situation, the electro-hydraulic cylinder 5 is controlled to extend, the piston shell 2 is synchronously driven to move upwards, the first air inlet 2002 is staggered with the upper row of second air inlets 4001, the upper row of second air inlets 4001 are blocked by the area of the piston shell 2 without the first air inlet 2002, meanwhile, the supporting seat 2003 is separated from the inner bottom surface of the base 1, after the piston shell 2 moves upwards, the lower row of second air inlets 4001 are completely exposed, the electro-hydraulic cylinder 5 is controlled to be closed, the inner diameter of the lower second air inlets 4001 is larger than the inner diameter of the upper second air inlets 4001, so that the air flow entering the confluence cabin 4003 through the lower second air inlets 4001 is increased, more air is discharged from the first air inlets 2002, more water vapor is taken out of the disinfection cabin 4005, the air is purified nearby the air disinfection machine module except for larger air quantity, and the air is humidified to a certain extent.

Working state when no person is around the air sterilizer module:

on the basis of the situation, the electric hydraulic cylinder 5 is controlled to extend continuously, the piston housing 2 moves upwards continuously, the four first pull ropes 11 are pulled by the piston housing 2, after the first pull ropes 11 are tensioned, the piston housing 2 drives the two ozone absorbers 9 to move upwards through the first pull ropes 11 and the fixing plates 10, when the ozone absorbers 9 are pulled out of the air boxes 8, the air boxes 8 do not purify ozone in the sterilized air any more, but directly discharge the ozone into the space, and as no people exist in the space, when the purified air is discharged into the space, the ozone is also discharged into the space, the air is sterilized in an all-round manner, the sterilizing time of the air sterilizer module is controlled according to different space sizes, after the sterilization is completed, half an hour of time is required for ozone to decompose into oxygen, the ozone is prevented from affecting the respiratory tract of a human body, or under the condition that the time condition is not allowed, the ultraviolet light can be matched for irradiation, the decomposition of the ozone is accelerated, and the ozone decomposition time is shortened.

Example 2

On the basis of the 1 st embodiment, according to fig. 1 and 6-8, the ozone generator further comprises an air duct 101 and an ozone tube 102; the air outlet of each air pump 7 is respectively communicated with an air duct 101, and a one-way valve is arranged in the air duct 101; the air duct 101 is positioned in the disinfection cabin 4005; every two adjacent air guide pipes 101 are contacted; each air duct 101 is provided with a plurality of air outlets; the front part and the rear part of the guide pipe of the ozone generator 6 are respectively communicated with two ozone pipes 102, and a one-way valve is arranged in each ozone pipe 102; the ozone tube 102 is positioned in the disinfection cabin 4005; every two adjacent ozone pipes 102 are in contact; a plurality of air outlets are provided on each ozone tube 102.

The air outlet of the air duct 101 is arranged at the lower part of the air duct, and the air outlets are arranged in a splayed shape, so that the air discharged by the air duct 101 is discharged to the disinfection cabin 4005 obliquely downwards, and the contact time of the air and ozone water in the disinfection cabin 4005 is increased.

The air outlet of the ozone pipe 102 is arranged at the lower part of the sterilizing cabin 4005, and the two rows of air outlets are in splayed symmetry, so that ozone discharged from the air outlet of the ozone pipe 102 is discharged downwards in an inclined way to the sterilizing cabin 4005, the contact time of the ozone and tap water in the sterilizing cabin 4005 is prolonged, and the ozone is fully dissolved in water.

The air duct 101 is arranged in parallel with the adjacent ozone pipe 102, so that the air discharged from the air outlet of the air duct 101 and the ozone discharged from the air outlet of the adjacent ozone pipe 102 are discharged to the disinfection cabin 4005 and are primarily mixed, and then the ozone is dissolved in water to fully disinfect the air.

When ozone water is used for disinfecting and purifying air, ozone and air are respectively introduced into tap water, because the positions of the ozone water and the air entering the tap water are relatively far apart, the mutual contact effect is poor, at the moment, as shown in fig. 6, ozone generated in an ozone generator 6 is filled into an ozone pipe 102, an air pump 7 is used for filling air into an air guide pipe 101, and because air outlets of the air guide pipe 101 and the ozone pipe 102 are arranged at the lower part, air discharged from the air guide pipe 101 and the ozone pipe 102 is obliquely downwards filled into tap water in a disinfection cabin 4005, the air is firstly downwards flushed out, then under the action of a floating force, the air floats to the surface of the water in the form of bubbles, so that the contact time of the air and the water is prolonged, meanwhile, the ozone is also dissolved in the tap water to form ozone water, after the ozone water enters the ozone water, the ozone water disinfects and purifies the outside air, and the outside air moves in the ozone water in a small bubble form, so that the outside air is effectively disinfected fully.

As shown in fig. 8, the air duct 101 and the ozone tube 102 are placed in parallel at the same time, so that when the air sprayed from the air duct 101 and the ozone tube 102 is sprayed downwards to the disinfection cabin 4005 in an inclined manner, the air can be mixed with ozone primarily, the ozone gas primarily disinfects and purifies the air, then the air floats upwards in the form of small bubbles, and in the floating process, the air in the disinfection cabin 4005 is disinfected by ozone water, so that the disinfection of the air is more thorough.

Example 3

On the basis of the 2 nd embodiment, according to fig. 1 and 9-11, the electric rotating plate 201, the condensation pipe 202, the guide strip 203 and the liquid collecting box 204 are also included; the upper part of the piston shell 2 is provided with two containing grooves 2004 which are distributed back and forth; each accommodating groove 2004 is rotatably connected with an electric rotating plate 201; the rotation directions of the two electric rotating plates 201 are opposite; one side of each electric rotating plate 201 facing the piston shell 2 is provided with an air guide groove 20101; a plurality of condensation pipes 202 are respectively arranged in each air guide groove 20101; a plurality of drain grooves 20102 are respectively formed in the lower part of each electric rotating plate 201; each drain groove 20102 corresponds to an adjacent one of the condensation pipes 202; the upper part of the base 1 is connected with a plurality of two guide strips 203 which are distributed back and forth; the guide strip 203 is made of fiber cotton; each guide bar 203 is positioned below one drain groove 20102; the upper part of the inner side of the base 1 is provided with two liquid collecting boxes 204 which are distributed front and back; each drip box 204 is located below one of the guide bars 203.

As shown in fig. 1 and 12-13, a side guard 301 is also included; two side guard plates 301 distributed left and right are welded on the upper part of the piston shell 2; the lower parts of all the side guard plates 301 are connected with the base 1 in a sliding way; each of the side guard plates 301 has a bending portion 30101 at the front and rear thereof; each side guard 301 is matched with one electric rotating plate 201 and used for shielding a gap between the upper part of the base 1 and the upper part of the piston shell 2; a hidden groove 30102 is respectively formed at the front part and the rear part of each side guard 301; each hidden groove 30102 is connected with a wind guide pipe 30103; the air guide pipe 30103 is aligned with the gap position between the piston shell 2 and the electric rotating plate 201, and the air guide pipe 30103 is communicated with the corresponding gap; a perforated plate 30104 is welded into each air guide pipe 30103.

The bottom of the hiding groove 30102 is inclined downwards, so that the hiding groove 30102 is bell-mouth-shaped and is used for preventing sundries from being plugged into the hiding groove 30102, and the sundries are not easy to discharge.

The perforated plate 30104 is inclined, is hidden in the corresponding air guide pipe 30103 and is used for guiding out the air direction in the air guide pipe 30103 obliquely downwards, and the perforated plate 30104 is positioned on one side of the air guide pipe 30103, so that air outlets on the perforated plate 30104 are not easy to be blocked.

When a person sits on the piston housing 2, even if the air is disinfected and purified by the small air inlet of the second air inlet 4001 above, after the disinfection and purification of the air are completed, when the air is discharged from the disinfection cabin 4005, the moisture in the disinfection cabin 4005 is discharged outwards along with the air, if the person sits on the piston housing 2 for a long time, the disinfected air is discharged from the air outlet 2001, the disinfected air is directly discharged to the position below the knee of the sitting person, so that the trousers of the person are wetted, as shown in fig. 9, the two electric rotating plates 201 are controlled to turn downwards, so that the two electric rotating plates 201 are matched with the side guard plates 301, the upper gaps of the base 1 and the piston housing 2 are blocked, the air with the moisture are prevented from being directly contacted with the trousers of the person, at this time, the air discharged from the air outlet 2001 is wetted with the air guide grooves 20101 of the electric rotating plates 201 and the condensation pipes 202, after encountering the condensation pipes 202, the moisture is condensed, as shown in fig. 11, the condensed drops on the condensation pipes 202 are directly discharged to the position below the knee of the sitting person, the condensation pipes 203 are also guided to the condensation water drops 203, and drop down to the outside through the condensation strips 203, and the condensation water drops 203, and the condensation boxes are also can not be guided to the condensation boxes, and the condensation boxes are guided to the outside, and the liquid drop strips 203 are finally, and the liquid drop collector boxes 203.

Meanwhile, the side guard 301 also moves downwards along with the piston shell 2, so that fingers can be effectively prevented from extending into the gap between the piston shell 2 and the base 1 when a person sits on the piston shell 2, if the electric hydraulic cylinder 5 is out of control, the piston shell 2 is damaged, the upper part of the piston shell 2 is close to the top of the base 1, hands are injured by clamping, meanwhile, when a child sits on the piston shell 2, the child grabs the upper edge of the piston shell 2 upwards through hands, if the electric hydraulic cylinder 5 is out of control, the piston shell 2 is damaged, the child is also easily injured by clamping fingers, the electric rotating plate 201 is turned out of the storage groove 2004, the fingers can be prevented from extending into the gap between the upper part of the piston shell 2 and the top of the base 1, meanwhile, the electric rotating plate 201 is turned downwards to block the exhaust port 2001, sterilized air is prevented from being directly blown to eyes of the child, discomfort of eyes is caused, and a condenser tube 202 is arranged on the electric rotating plate 201, and the sterilized air is cooled by the condenser tube 202, so that the sterilized air is also cooled by the cooling air on the piston shell 2, and the sterilized air can be cooled by the cooling air.

As shown in fig. 12 and 13, after the electric rotating plate 201 is opened downwards, an air channel is formed between the electric rotating plate 201 and the piston housing 2, the sterilized air flows to the left and right sides along the air channel, then enters the air guide pipe 30103 and is discharged from the porous plate 30104, wherein the porous plate 30104 is arranged in a hidden downwards inclined mode, the phenomenon that a child sees the porous plate 30104 to block a cavity on the porous plate 30104 is effectively avoided, the lower part of the hidden groove 30102 is arranged downwards inclined, so that the sundries plugged into the hidden groove 30102 cannot be sufficiently fixed by holes on the porous plate 30104, even if objects exist in the hidden groove 30102, the sundries can be blown out from the hidden groove 30102 through increasing ventilation power, and then the sundries are cleaned by the internet of things contact sanitation staff.

When no person sits on the piston housing 2, but there is still a person around, the electric rotating plate 201 is stored in the storage groove 2004, and the sterilizing air and moisture discharged from the air outlet 2001 are directly discharged to the outside, thereby performing cyclic sterilization and humidification dust fall on the outside air.

According to fig. 1 and 14-15, the device further comprises a sliding rod 401, a baffle 402, an elastic piece 403, a connecting rod 404 and a second pull rope 405; the upper part of the inner side of the piston shell 2 is welded with a front sliding rod 401 and a rear sliding rod 401 respectively; a plurality of baffle plates 402 are respectively connected to the two adjacent slide bars 401 in a sliding way; each baffle plate 402 is fixedly connected with two elastic pieces 403 which are distributed up and down; the elastic member 403 is a spring; each sliding rod 401 is fixedly connected with a corresponding elastic piece 403; a connecting rod 404 is welded at the lower part of the baffle 402 at the same side; each connecting rod 404 is fixedly connected with two second pull ropes 405; all the second pull ropes 405 are fixedly connected with the top of the disinfection box 4 together; each flap 402 mates with one exhaust port 2001; the fixed position of the second pull rope 405 and the sterilizing compartment 4 and the fixed position of the second pull rope 405 and the connecting rod 404 are not on the same horizontal line.

When no people are around, ozone is directly discharged into the environment, the environment is effectively disinfected in all directions, as shown in fig. 14 and 15, at this time, based on the situation, the electric hydraulic cylinder 5 is controlled to continue to extend, the piston housing 2 is synchronously driven to move upwards, after the piston housing 2 drives the sliding rod 401 and corresponding parts on the sliding rod 401 to move together, each connecting rod 404 also pulls two second pull ropes 405, as the piston housing 2 moves upwards, the second pull ropes 405 are tensioned, because the fixed positions of the second pull ropes 405 and the disinfection box 4 and the fixed positions of the second pull ropes 405 and the connecting rods 404 are not on the same horizontal line, as the piston housing 2 moves upwards, the second pull ropes 405 pull the connecting rods 404 to move, the corresponding elastic pieces 403 are stretched, wherein the direction of the movement of the connecting rods 404 is that the horizontal relative positions of the fixed positions of the second pull ropes 405 and the connecting rods 404 are the horizontal relative positions of the fixed positions of the second pull ropes 405 and the disinfection box 4, as shown in fig. 15, namely, the connecting rods 404 also drive the corresponding baffle plates 402 to move rightwards from left to right, and each baffle plates 402 are tensioned, and the corresponding exhaust ports 2001 part is blown out, so that the air is completely disinfected in the places through 2001, and the places can be completely disinfected by blowing out.

The foregoing has outlined rather broadly the more detailed description of the present application, wherein specific examples have been provided to illustrate the principles and embodiments of the present application, the description of the examples being provided solely to assist in the understanding of the method of the present application and the core concepts thereof; meanwhile, as those skilled in the art will have modifications in the specific embodiments and application scope in accordance with the ideas of the present application, the present description should not be construed as limiting the present application in view of the above.

Claims (9)

1. An efficient air sterilizer based on the Internet of things comprises a base (1); a piston shell (2) is movably connected on the base (1); the inside of the base (1) is hollowed out; a cushion is laid on the upper surface of the piston shell (2), and a pressure sensor is arranged on the piston shell (2); a plurality of rows of first air inlets (2002) are formed in the piston shell (2); a plurality of rows of exhaust ports (2001) are formed in the piston shell (2); the exhaust port (2001) is positioned above the first air inlet (2002); a supporting seat (2003) is fixedly connected to the lower part of the piston shell (2); the supporting seat (2003) is contacted with the inner bottom of the base (1); a plurality of dustproof nets (3) are detachably connected to the base (1); the method is characterized in that: also comprises a disinfection box (4); a plurality of disinfection boxes (4) are fixedly connected at the inner bottom of the base (1); a plurality of electro-hydraulic cylinders (5) are arranged at the inner bottom of the base (1); all the electric hydraulic cylinders (5) are positioned between two adjacent disinfection boxes (4); all the telescopic parts of the electric hydraulic cylinders (5) are fixedly connected with the inner top of the piston shell (2) together; an ozone generator (6) is fixedly connected at the inner bottom of the base (1), and a one-way valve is arranged in a conduit of the ozone generator (6); the ozone generator (6) is positioned between two adjacent electro-hydraulic cylinders (5); a plurality of air pumps (7) are respectively arranged in each disinfection box (4); two rows of second air inlets (4001) are respectively formed in one side, far away from the ozone generator (6), of each disinfection box (4), and the inner diameter of the second air inlet (4001) above is smaller than that of the second air inlet (4001) below; the upper row of second air inlets (4001) is matched with the adjacent first air inlets (2002); a sensor is arranged in the second air inlet (4001); a first clapboard (4002) is fixedly connected in each disinfection box (4); each first partition board (4002) divides the internal space of one disinfection box (4) into two cavities, and a confluence cabin (4003) is arranged in each disinfection box (4) far away from the ozone generator (6); two second clapboards (4004) are fixedly connected with a cavity of one side of each first clapboard (4002) close to the ozone generator (6); every two second partition boards (4004) are fixedly connected with the inner wall, close to the ozone generator (6), in the disinfection box (4); each air pump (7) is positioned in a space surrounded by the corner of one disinfection box (4), the first partition board (4002) and the second partition board (4004); the cavity between every two adjacent second partition boards (4004) is a disinfection cabin (4005); the disinfection cabin (4005) is communicated with a conduit of the ozone generator (6); the air inlets of every two adjacent air pumps (7) are communicated with one confluence cabin (4003) together; the air outlets of every two adjacent air pumps (7) are communicated with a disinfection cabin (4005) together; the upper part of each disinfection box (4) is respectively communicated with an air box (8); each bellows (8) is movably connected with an ozone absorber (9); the upper part of each ozone absorber (9) is fixedly connected with a fixing plate (10); the upper part of each fixed plate (10) is respectively connected with a plurality of first stay ropes (11); the upper parts of all the first pull ropes (11) are fixedly connected with the inner top surface of the piston shell (2) together;

also comprises an air duct (101); the air outlet of each air pump (7) is respectively communicated with an air duct (101), and a one-way valve is arranged in the air duct (101); the air duct (101) is positioned in the disinfection cabin (4005); every two adjacent air guide pipes (101) are contacted; each air duct (101) is provided with a plurality of air outlets; the front part and the rear part of the guide pipe of the ozone generator (6) are respectively communicated with two ozone pipes (102), and a one-way valve is arranged in each ozone pipe (102); the ozone pipe (102) is positioned in the disinfection cabin (4005); every two adjacent ozone pipes (102) are contacted; a plurality of air outlets are arranged on each ozone pipe (102).

2. The high-efficiency air sterilizer based on the internet of things according to claim 1, wherein: the air outlet of the air duct (101) is arranged at the lower part of the air duct, and the air outlets are arranged in two rows in a splayed shape.

3. The high-efficiency air sterilizer based on the internet of things according to claim 1, wherein: the air outlets of the ozone pipes (102) are arranged at the lower part of the ozone pipes, and the two rows of the air outlets are symmetric in a splayed shape.

4. The high-efficiency air sterilizer based on the internet of things according to claim 1, wherein: the air duct (101) is arranged in parallel with the adjacent ozone tube (102).

5. The high-efficiency air sterilizer based on the internet of things according to claim 1, wherein: the electric rotating plate (201) is also included; the upper part of the piston shell (2) is provided with a plurality of containing grooves (2004); each accommodating groove (2004) is rotatably connected with an electric rotating plate (201); one side of each electric rotating plate (201) facing the piston shell (2) is provided with an air guide groove (20101); a plurality of condensing pipes (202) are respectively arranged in each air guide groove (20101); a plurality of drain grooves (20102) are respectively formed in the lower part of each electric rotating plate (201); each drain groove (20102) corresponds to an adjacent condensing pipe (202); the upper part of the base (1) is connected with a plurality of guide strips (203); each guide strip (203) is positioned below one drain groove (20102); a plurality of liquid collecting boxes (204) are arranged at the upper part of the inner side of the base (1); each drip box (204) is positioned below one guide strip (203).

6. The internet of things-based efficient air sterilizer as set forth in claim 5, wherein: the device also comprises a side guard board (301); the upper part of the piston shell (2) is fixedly connected with a plurality of side guard plates (301); the lower parts of all the side guard plates (301) are connected with the base (1) in a sliding way; the front part and the rear part of each side guard plate (301) are respectively provided with a bending part (30101); each side guard plate (301) is matched with one electric rotating plate (201) and used for shielding a gap between the upper part of the base (1) and the upper part of the piston shell (2); the front part and the rear part of each side guard plate (301) are respectively provided with a hidden groove (30102); each hidden groove (30102) is connected with a wind guide pipe (30103); the air guide pipe (30103) is aligned with the gap position between the piston shell (2) and the electric rotating plate (201), and the air guide pipe (30103) is communicated with the corresponding gap; a porous plate (30104) is fixedly connected in each air guide pipe (30103).

7. The internet of things-based efficient air sterilizer as claimed in claim 6, wherein: the bottom of the hidden groove (30102) is inclined downwards.

8. The internet of things-based efficient air sterilizer as claimed in claim 6, wherein: the porous plates (30104) are inclined and are hidden in the corresponding air guide pipes (30103).

9. The high-efficiency air sterilizer based on the internet of things according to any one of claims 1 to 8, wherein: the device also comprises a sliding rod (401); a plurality of sliding bars (401) are fixedly connected to the upper part of the inner side of the piston shell (2); a plurality of baffle plates (402) are respectively connected to the two adjacent slide bars (401) in a sliding way; a plurality of elastic pieces (403) are fixedly connected to each baffle (402); each sliding rod (401) is fixedly connected with a corresponding elastic piece (403); the lower parts of the baffle plates (402) on the same side are fixedly connected with a connecting rod (404) together; each connecting rod (404) is fixedly connected with two second stay ropes (405); all the second pull ropes (405) are fixedly connected with the top of the disinfection box (4) together; each baffle (402) is matched with one exhaust port (2001); the fixed position of the second stay rope (405) and the disinfection box (4) and the fixed position of the second stay rope (405) and the connecting rod (404) are not on the same horizontal line.