CN114460236A

CN114460236A - Air quality monitoring method

Info

Publication number: CN114460236A
Application number: CN202210128328.6A
Authority: CN
Inventors: 柏振华
Original assignee: Individual
Current assignee: Qinhuangdao Yunlifang Technology Co ltd
Priority date: 2022-02-11
Filing date: 2022-02-11
Publication date: 2022-05-10
Anticipated expiration: 2042-02-11
Also published as: CN114460236B

Abstract

The invention discloses an air quality monitoring method, which is characterized by comprising the following steps: the method comprises the following specific steps: the method comprises the following steps: the method comprises the following steps of stably placing a clip-shaped shell of the air quality monitoring device on the bottom surface of the air quality to be monitored; step two: starting the turnover mechanism to drive the air monitor (2) in a horizontal state to slowly cross over the bottom of the clip-shaped shell (1), and turning the air monitor (2) to the top of the clip-shaped shell (1); step three: two sets of air monitors are vertically arranged in the air, and monitor the air quality: step four: after the monitoring is finished, the turnover mechanism reversely rotates, the air monitor (2) which is monitored is withdrawn into the clip-shaped shell (1) again, and the air monitor is sealed again; step five: the flushing mechanism is started to flush the head of the air monitor (2) to complete one-time monitoring.

Description

Air quality monitoring method

Technical Field

The invention relates to the technical field of air quality monitoring, in particular to an air quality monitoring method.

Background

The air quality is related to the health of people, and people discharge various harmful gases in production and life to cause air pollution. For example, in the processes of industrial production, transportation, house decoration, and the like, harmful gases such as hydrogen sulfide, carbon dioxide, carbon monoxide, nitrogen oxides, ozone, and the like are easily generated, which brings harm to human health and also has adverse effects on industrial and agricultural production and climate.

When the air monitoring device in the prior art monitors air, the monitoring precision is reduced, the air monitoring device is mainly embodied in two aspects, firstly, only a group of monitors are adopted to monitor air, the collected data is less, the monitoring error is easy to appear, secondly, the existing monitors are still exposed in the air for a long time after monitoring, and impurities in the dust or air monitoring process can be possibly remained on the surfaces or the inside of the monitors, so that the monitoring is inaccurate next time.

Based on the above, the invention designs an air quality monitoring method to solve the above problems.

Disclosure of Invention

The invention aims to provide an air quality monitoring method, which aims to solve the problem that when the air monitoring device in the prior art is used for monitoring air, the monitoring precision is reduced, and the two aspects are mainly embodied.

In order to achieve the purpose, the invention provides the following technical scheme: the air quality monitoring method is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: the method comprises the following steps of stably placing a clip-shaped shell of the air quality monitoring device on the bottom surface of the air quality to be monitored;

step two: starting the turnover mechanism to drive the air monitor (2) in a horizontal state to slowly cross over the bottom of the clip-shaped shell (1), and turning the air monitor (2) to the top of the clip-shaped shell (1);

step three: two sets of air monitors are vertically arranged in the air, and monitor the air quality:

step four: after the monitoring is finished, the turnover mechanism reversely rotates, the air monitor (2) which is monitored is withdrawn into the clip-shaped shell (1) again, and the air monitor is sealed again;

step five: the flushing mechanism is started to flush the head of the air monitor (2) to complete one-time monitoring.

In the scheme, the air quality monitoring device comprises a clip-shaped shell (1), two groups of air monitors (2) which are symmetrically arranged at the front and back of the inner side of the clip-shaped shell (1) are arranged at the inner side of the clip-shaped shell (1), and the front and back side walls of the clip-shaped shell (1) are connected with a turnover mechanism for driving the two groups of air monitors (2) to be turned over to the top of the clip-shaped shell (1) from the inside of the clip-shaped shell; the turnover mechanism enables the air monitor (2) to be positioned at the top of the clip-shaped shell (1) and keep a vertical state when monitoring air, and a flushing mechanism for cleaning the horizontal air monitor (2) is arranged on the inner side of the clip-shaped shell (1); the turnover mechanism enables the air monitor (2) to be in a horizontal state and matched with the flushing mechanism to clean the air monitor (2) when the air monitor (2) is stored inside the square-shaped shell (1).

In the scheme, a positioning hole (27) is formed in the outer surface of each air monitor (2), a plurality of second supporting plates (28) are fixedly connected to the inner side wall of the turnover plate (6), a positioning rod (29) is slidably connected to the inner part of each second supporting plate (28), and the positioning rod (29) is inserted into the positioning hole (27) to position the air monitor (2); a first baffle disc (30) is fixedly connected to the outer surface of each positioning rod (29), and a second spring (31) positioned between the first baffle disc (30) and the second supporting plate (28) is sleeved on the outer surface of each positioning rod (29); the inner end of each positioning rod (29) is fixedly connected with a guide plate (32), a plurality of extrusion inclined plates (33) are fixedly connected to the inner side wall of the square-shaped shell (1), and the extrusion inclined plates (33) are used for extruding the guide plates (32) to enable the guide plates to move inwards to pull out the positioning rods (29) from the positioning holes (27).

In the scheme, a water outlet groove (34) is formed in the bottom of the clip-shaped shell (1), a water storage groove (35) is fixedly communicated with the bottom of the clip-shaped shell (1), and the water storage groove (35) is communicated with the water outlet groove (34); two groups of inclined guide blocks (36) which are positioned at the front side and the rear side of the water outlet groove (34) are fixedly connected to the bottom surface of the inner side of the square-shaped shell (1), the inclined guide blocks (36) are used for guiding the cleaned water outlet groove (34) of the water tank, and an inclined plate (37) is fixedly connected to the outer surface of each sealing plate (12); the inclined plate (37) is connected to the inner side face of the inclined guide block (36) in a sliding mode, the sealing plate (12) is connected with the inclined guide block (36) in a sliding mode, and the inclined guide block (36) and the inclined plate (37) form a sealed guide inclined face together.

In the scheme, a plurality of second sliding rods (38) in sliding connection with the second sliding rods penetrate through the top of the square-shaped shell (1), a rectangular lifting plate (39) is fixedly connected to the top ends of the second sliding rods (38) together, and a fourth spring (40) located between the rectangular lifting plate (39) and the square-shaped shell (1) is sleeved on the outer surface of each second sliding rod (38).

In the scheme, the opening and closing mechanism comprises a plurality of groups of first air springs (7) with the same number as that of the air monitors (2), each group of first air springs (7) are fixedly connected to the inner top surface of the clip-shaped shell (1), and the bottoms of the same group of first air springs (7) are fixedly connected with a U-shaped lifting frame (8) together; a first extrusion block (9) is fixedly connected to the left and right side walls inside each U-shaped lifting frame (8), an ejector rod (10) is fixedly connected to the outer surface of each air monitor (2), the ejector rods (10) are used for jacking the U-shaped lifting frames (8), a plurality of through grooves (11) located right below the air monitors (2) are formed in the bottom of the clip-shaped shell (1), and the through grooves (11) are used for the air monitors (2) to pass through when the air monitors (2) are turned over; two sealing plates (12) which are connected to the inner side wall of the clip-shaped shell (1) in a sliding mode are arranged above each through groove (11), a first sliding rod (13) is fixedly connected to the outer side wall of each sealing plate (12), and a first supporting block (14) is fixedly connected to the bottom surface inside the clip-shaped shell (1); the first sliding rods (13) penetrate through the first supporting blocks (14) and are in sliding connection with the first supporting blocks, and a first spring (15) fixedly connected between the sealing plate (12) and the first supporting blocks (14) is sleeved on the outer surface of each first sliding rod (13); the outer end of each first sliding rod (13) is fixedly connected with a second extrusion block (17) through a first connecting frame (16), and the second extrusion blocks (17) are used for acting with the first extrusion blocks (9).

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

1. according to the invention, when the air quality needs to be monitored each time, the two groups of air monitors are accommodated and opened by utilizing the mutual matching of the clip-shaped shell and the turnover mechanism, so that the air monitors are positioned at the top of the clip-shaped shell during monitoring, the air is monitored more accurately, and after the monitoring is finished, the air monitors are horizontally accommodated in the clip-shaped shell, so that the flushing mechanism only flushes the head part of the air monitor, thereby avoiding excessive influence on other mechanisms of the air monitor, taking out particle impurities remained on the outer surface of the air monitor, and improving the accuracy of the next monitoring.

2. According to the invention, after the air monitor is reset, the two first electric cylinders are started, and simultaneously drive the extrusion plate to extrude the cleaning bag, so that the cleaning solution in the cleaning bag is sprayed out from the spray head, the horizontally arranged air monitor is monitored and washed, particle impurities adhered to the surface of the air monitor are taken out, the impurities remained on the surface influence the next air monitoring, and the monitoring accuracy of the air monitor is improved.

Drawings

FIG. 1 is a flow chart of the present invention;

FIG. 2 is a first perspective view of the overall configuration of a monitoring device employed in the present invention;

FIG. 3 is a second perspective cross-sectional view of the overall construction of a monitoring device employed in the present invention;

FIG. 4 is a third perspective cross-sectional view of the overall construction of a monitoring device employed in the present invention;

FIG. 5 is a fourth perspective cross-sectional view of the overall construction of a monitoring device employed in the present invention;

FIG. 6 is a fifth perspective cross-sectional view of the overall construction of a monitoring device employed in the present invention;

FIG. 7 is a schematic view of the structure of the outside of the air detector inside the roll-over plate of the monitoring device used in the present invention;

FIG. 8 is an enlarged view of the structure of FIG. 7 at A;

FIG. 9 is a schematic view of the left side of the cleaning mechanism of the monitoring device of the present invention;

fig. 10 is a schematic diagram of the positions of the inclined guide block and the inclined plate and the sealing plate of the monitoring device adopted by the invention.

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

the device comprises a clip-shaped shell 1, an air monitor 2, a first connecting plate 3, a first rotating rod 4, a first motor 5, a turnover plate 6, a first air spring 7, a U-shaped lifting frame 8, a first extrusion block 9, a push rod 10, a through groove 11, a sealing plate 12, a first sliding rod 13, a first supporting block 14, a first spring 15, a first connecting frame 16, a second extrusion block 17, a cleaning bag 18, a first electric cylinder 19, an extrusion plate 20, a friction ring 21, a second connecting plate 22, a threaded rod 23, a threaded sleeve 24, a first fixing plate 25, a friction plate 26, a positioning hole 27, a second supporting plate 28, a positioning rod 29, a first baffle disc 30, a second spring 31, a guide plate 32, an extrusion inclined plate 33, a water outlet groove 34, a water storage groove 35, an inclined guide block 36, an inclined plate 37, a second sliding rod 38, a rectangular lifting plate 39 and a fourth spring 40.

Detailed Description

The invention provides a technical scheme that:

referring to fig. 1-10, an energy-saving and rapidly deployable air quality monitoring method includes the following specific steps:

referring to fig. 2-10, the air quality monitoring device includes a clip-shaped casing 1, two sets of air monitors 2 are symmetrically arranged on the inner side of the clip-shaped casing 1, and the front and rear side walls of the clip-shaped casing 1 are connected with a turnover mechanism for driving the two sets of air monitors 2 to turn over from the inside of the clip-shaped casing 1 to the top thereof. The turnover mechanism enables the air monitor 2 to be positioned at the top of the square-shaped shell 1 and keep a vertical state when monitoring air, and a flushing mechanism used for cleaning the horizontal air monitor 2 is arranged on the inner side of the square-shaped shell 1. When the turnover mechanism is used for accommodating the air monitor 2 into the inner side of the square-shaped shell 1, the air monitor 2 is in a horizontal state and is matched with the flushing mechanism to clean the air monitor 2;

when needs monitored the outside air, start earlier tilting mechanism and drive air monitor 2 that is in the horizontality and slowly cross shape casing 1 bottom, overturn air monitor 2 to the top of shape casing 1 of returning to make air monitor 2 be in vertical state, guarantee that it is located the top of shape casing 1 of returning, avoid shape casing 1 of returning to cause the influence to air monitor 2 in the monitoring process, improve the accuracy of monitoring. When two sets of air monitor 2 were overturned to the time of returning the shape casing 1 directly over, two sets of air monitor 2 started simultaneously, began to monitor the air, and two sets of air monitor 2 will carry out the structure of monitoring to the air and send to the collecting system in, carry out average calculation, obtain the more accurate air numerical value of at every turn when monitoring, improve the monitoring accuracy.

After the monitoring is accomplished at every turn, tilting mechanism antiport, take back the air monitor 2 that the monitoring was accomplished in time returning back shape casing 1, tilting mechanism and returning shape casing 1 mutual contact, the closure forms a complete airtight cavity, avoid accomplishing the back at the monitoring, air monitor 2 still leads to dust or particle impurity to pile up in air monitor 2 inside or on the surface with the outside air contact, the monitoring next time is influenced, and accomplish the back at every turn monitoring, return in the shape casing 1 with air monitor 2 income, avoid transporting the in-process, air monitor 2 collides and damages with other article. When two sets of air monitor 2 upset income time in returning shape casing 1, two sets of air monitor are in the horizontality, the mechanism that washes that is located 2 heads of air monitor directly over starts, only wash 2 heads of air monitor, avoid washing the in-process, the clear water flows to air monitor 2's other positions, damage air monitor 2, be favorable to guaranteeing when washing air monitor 2 at every turn, can not too much influence other parts, avoid other parts rainwater to damage or rusty condition to appear.

After the washing mechanism is cleaned, the air monitor 2 is horizontally arranged in the clip-shaped shell 1 for self-air-drying, and at the moment, the clip-shaped shell 1 is in a sealed environment to prevent external dust or particle impurities from polluting the air monitor 2 again, which is beneficial to ensuring the accuracy of next monitoring of the air monitor 2, thereby realizing that when the air quality needs to be monitored each time, the clip-shaped shell 1 and the turnover mechanism are mutually matched to realize the storage and the opening of two groups of air monitors 2, so that the air monitor 2 is positioned at the top of the clip-shaped shell 1 during monitoring to monitor the air more accurately, after the monitoring is finished, the air monitor 2 is horizontally stored in the clip-shaped shell 1, so that the washing mechanism only washes the head part of the air monitoring, thereby avoiding excessive influence on other mechanisms of the air monitor 2 and removing the particle impurities staying on the outer surface of the air monitor 2, the accuracy of the next monitoring is improved.

Referring to fig. 2-10, the turnover mechanism includes two sets of first connecting plates 3, each set of two first connecting plates 3 are respectively and fixedly connected to the front and rear side walls of the rectangular casing 1, the inner side walls of the two first connecting plates 3 on the same side are connected with first rotating rods 4 in a rotating mode, the right ends of the two first rotating rods 4 are respectively and fixedly connected with first motors 5, and the first motors 5 are fixedly connected to the outer side walls of the rectangular casing 1. Equal fixedly connected with returning face plate 6 on the 4 surfaces of two first bull sticks, both sides are sealed around two returning face plates 6 will return shape casing 1 around, and two sets of air monitor 2 are connected respectively in the inside wall of two returning face plates 6 in the front and back, and returning face plate 6 is used for driving air monitor 2 and rotates. The bottom of the square-shaped shell 1 is provided with an opening and closing mechanism for the air monitor 2 to pass through when the air monitor 2 is turned over, the opening and closing mechanism is opened when the air monitor 2 is turned over, and the air monitor 2 is closed after being stored after monitoring is completed;

referring to fig. 2-10, the opening and closing mechanism comprises a plurality of groups of first air springs 7 with the same number as the air monitors 2, each group of first air springs 7 is fixedly connected to the top surface of the inside of the clip-shaped shell 1, the bottoms of the first air springs 7 in the same group are fixedly connected with U-shaped lifting frames 8, and the left and right side walls of the inside of each U-shaped lifting frame 8 are fixedly connected with first extrusion blocks 9. Equal fixedly connected with ejector pin 10 on every air monitor 2's the surface, ejector pin 10 is used for jack-up U type crane 8, and a plurality of logical grooves 11 that are located under air monitor 2 are seted up to shape casing 1 bottom, lead to groove 11 and supply it to pass when air monitor 2 overturns. Two sealing plates 12 which are connected to the inner side wall of the square-shaped shell 1 in a sliding mode are arranged above each through groove 11, a first sliding rod 13 is fixedly connected to the outer side wall of each sealing plate 12, a first supporting block 14 is fixedly connected to the bottom surface of the inside of the square-shaped shell 1, the first sliding rod 13 penetrates through the first supporting block 14 and is connected with the first supporting block in a sliding mode, a first spring 15 fixedly connected between the sealing plates 12 and the first supporting block 14 is sleeved on the outer surface of each first sliding rod 13 in a sleeved mode, the outer end of each first sliding rod 13 is fixedly connected with a second extrusion block 17 through a first connecting frame 16, and the second extrusion block 17 is used for acting with the first extrusion block 9;

when the air monitor is in operation, the air monitor 2 needs to be turned over to the top of the clip-shaped shell 1 and is ensured to be in a vertical state, the first motor 5 is started, the first motor 5 drives the first rotating rod 4 and the turning plate 6 to rotate, the turning plate 6 drives the air monitor 2 connected to the inner side wall of the turning plate to turn downwards, the air monitor 2 drives the ejector rod 10 at the top of the air monitor to move downwards, so that the ejector rod 10 is separated from jacking the U-shaped lifting frame 8, the U-shaped lifting frame 8 moves downwards under the action of the first air spring 7 to drive the two first extrusion blocks 9 to move downwards, the first compression block slides down the second extrusion block 17, the first spring 15 pulls the sealing plate 12 to move outwards, so that the second extrusion block 17 moves outwards, the second extrusion block 17 drives the first sliding rod 13 and the sealing plate 12 to move outwards through the first connecting frame 16, so that the two sealing plates 12 of the sealing through groove 11 are opened towards two sides, when air monitor 2 is driven to overturn to logical groove 11 top, sealing plate 12 has thoroughly opened, thereby make air monitor 2 pass through in leading to groove 11, after air monitor 2 crossed logical groove 11, returning face plate 6 continues to rotate, drive air monitor 2 and slowly overturn to returning back shape casing 1 directly over, returning face plate 6 finally overturns 270 and is in the horizontality, and stand directly over returning back shape casing 1 with its vertical air monitor 2 side of being connected is vertical upwards, avoid returning back shape casing 1 to block that the gas flows the monitoring that influences air monitor 2.

In the same way, when the air monitor 2 needs to be retracted, the through groove 11 is always in the open state, when the air monitor 2 is driven to turn over into the square shell 1 again, the top rod 10 at the top of the air monitor 2 jacks up the U-shaped lifting plate, the first air spring 7 is compressed, the first extrusion block 9 is driven to move upwards, the second extrusion block 17 is extruded, the second extrusion block 17 and the first sliding rod 13 move inwards, the first spring 15 is compressed, the first sliding rod 13 drives the sealing plate 12 to move towards the top of the through groove 11, so that the two sealing plates 12 are slowly closed, when returning to the throne at returning face plate 6 and air monitor 2, two closing plates 12 will lead to groove 11 and accomplish sealedly, guarantee that the external air of monitoring back lasts to flow into back shape casing 1 in, contaminated air monitor 2 avoids the long-time and 2 contact of air monitor of particle impurity of air to pile up, is favorable to improving air monitor 2's monitoring result.

Referring to fig. 2-10, the flushing mechanism includes a cleaning bag 18, the bottom of the cleaning bag 18 is fixedly communicated with a plurality of nozzles, the inner side of the square-shaped shell 1 is fixedly connected with two first electric cylinders 19, the two first electric cylinders 19 are respectively positioned at the front and rear sides of the cleaning bag 18, the inner ends of the two first electric cylinders 19 are fixedly connected with extrusion plates 20, and the front and rear extrusion plates 20 are used for extruding the cleaning bag 18;

the during operation, because need wash the air monitor 2 of aquatic products, after air monitor 2 resets, start two first electric jars 19, two first electric jars 19 drive stripper plate 20 extrusion cleaning bag 18 simultaneously, make the inside cleaning solution of cleaning bag 18 spout from the shower nozzle, wash the air monitor 2 monitoring of horizontal arrangement, take out the granule impurity of adhesion at the air monitoring surface, the impurity that the surface stops influences the monitoring of air monitoring next time, be favorable to improving the accuracy of air monitor 2 monitoring.

Referring to fig. 2-10, the air monitors 2 are rotatably connected to the inner side wall of the turning plate 6, the outer surface of each air monitor 2 is fixedly connected with a friction ring 21, the bottom of each extrusion plate 20 is fixedly connected with a second connecting plate 22, and the outer side wall of each second connecting plate 22 is fixedly connected with a threaded rod 23. The threaded rod 23 is sleeved with a threaded sleeve 24 on the outer surface, a first fixing plate 25 is rotatably connected to the outer surface of the threaded sleeve 24, the first fixing plate 25 is fixedly connected to the inner side wall of the clip-shaped shell 1, a friction plate 26 is slidably connected to the bottom of the first fixing plate 25, and the friction plate 26 is in contact with two friction rings 21 and the threaded sleeve 24 on the same side.

During operation, because when the shower nozzle sprays the cleaning solution to air monitor 2 and cleans, the part of air monitor 2 bottom probably can't contact with the cleaning solution, air monitor 2 is clean incomplete easily to appear, through the in-process at the inside extrusion clean bag 18 play water of stripper plate 20, stripper plate 20 drives threaded rod 23 through second connecting plate 22 and inwards moves, make threaded bush 24 take place to rotate, 24 surface drive friction plate 26 of threaded bush move to the left side, friction plate 26 drives air monitor 2 through two friction ring 21 and lasts the rotation at the cleaning in-process, make every face homoenergetic of air monitor 2 just right with the shower nozzle at top, make air monitor 2 can more thoroughly be cleaned.

Referring to fig. 2-10, each air monitor 2 has a positioning hole 27 formed on its outer surface, a plurality of second support plates 28 are fixedly connected to the inner side walls of the turnover plates 6, a positioning rod 29 is slidably connected to the inside of each second support plate 28, the positioning rod 29 is inserted into the positioning hole 27 to position the air monitor 2, a first baffle disc 30 is fixedly connected to the outer surface of each positioning rod 29, a second spring 31 located between the first baffle disc 30 and the second support plate 28 is sleeved on the outer surface of the positioning rod 29, a guide plate 32 is fixedly connected to the inner end of each positioning rod 29, a plurality of extrusion inclined plates 33 are fixedly connected to the inner side walls of the clip-shaped shell 1, and the extrusion inclined plates 33 are used for extruding the guide plate 32 to move inwards to pull out the positioning rod 29 from the positioning hole 27.

The during operation, because air monitor 2 rotates to be connected on returning face plate 6, when it monitors, probably drive spontaneous rotation by the outside air, can influence the monitoring, when outwards overturning through utilizing air monitor 2, guide board 32 slowly breaks away from with extrusion swash plate 33, guide board 32 breaks away from the extrusion of extrusion swash plate 33, first fender dish 30 of second spring 31 extrusion, make first fender dish 30, locating lever 29 and guide board 32 outwards remove in step, make locating lever 29 insert in air monitor 2's locating hole 27, peg graft fixedly with air monitor 2 and returning face plate 6, avoid air monitor 2 to take place to rotate when the monitoring, be favorable to improving air monitor's the degree of accuracy.

Referring to fig. 2-10, a water outlet groove 34 is formed in the bottom of the square-shaped shell 1, the bottom of the square-shaped shell 1 is fixedly communicated with a water storage groove 35, the water storage groove 35 is communicated with the water outlet groove 34, two groups of inclined guide blocks 36 are fixedly connected to the bottom surface of the inner side of the square-shaped shell 1 and located on the front side and the rear side of the water outlet groove 34, the inclined guide blocks 36 are used for guiding the cleaned water tank water outlet groove 34, and an inclined plate 37 is fixedly connected to the outer surface of each sealing plate 12. The inclined plate 37 is connected to the inner side surface of the inclined guide block 36 in a sliding manner, the sealing plate 12 is connected to the inclined guide block 36 in a sliding manner, and the inclined guide block 36 and the inclined plate 37 on the same side form a sealed guide inclined surface together.

The during operation, because when washing mechanism and washing air monitor 2, the cleaning solution body can be in disorder to flow, can influence and arrange the normal motion of other mechanisms in returning shape casing 1 inboard, through utilizing oblique guide block 36, closing plate 12 and oblique template 37 to form the guide inclined plane jointly, guide in the cleaning solution case outlet chute 34 after will cleaning, directly fall and collect in catch basin 35, avoid the cleaning solution dispersion to influence other structures in the inboard of returning shape casing 1.

Referring to fig. 2-10, a plurality of second sliding rods 38 slidably connected with the clip-shaped housing 1 penetrate through the top of the clip-shaped housing 1, a rectangular lifting plate 39 is fixedly connected to the top ends of the plurality of second sliding rods 38, and a fourth spring 40 positioned between the rectangular lifting plate 39 and the clip-shaped housing 1 is sleeved on the outer surface of each second sliding rod 38; because the roll-over plate 6 when overturning to the top of returning the shape casing 1, can collide with respiratory tube casing top, through the fourth spring 40 and the rectangle lifter plate 39 that set up at returning the shape casing 1 top, to the roll-over plate 6 elastic connection of upset, avoid roll-over plate 6 and arc casing to collide, protect the air monitor 2 who is connected with roll-over plate 6.

Step two: starting the turnover mechanism to drive the air monitor 2 in a horizontal state to slowly cross over the bottom of the clip-shaped shell 1, and turning the air monitor 2 to the top of the clip-shaped shell 1;

step four: after the monitoring is finished, the turnover mechanism reversely rotates, the air monitor 2 which is monitored is retracted into the clip-shaped shell 1 again, and the air monitor is sealed again;

step five: the flushing mechanism is started to flush the head of the air monitor 2, and one-time monitoring is completed.

Claims

1. The air quality monitoring method is characterized by comprising the following steps: the method comprises the following steps:

2. The air quality monitoring method according to claim 1, characterized in that: the air quality monitoring device comprises a clip-shaped shell (1), wherein two groups of air monitors (2) which are symmetrically arranged at the front and back of the inner side of the clip-shaped shell (1) are arranged at the inner side of the clip-shaped shell (1), and the front and back side walls of the clip-shaped shell (1) are connected with a turnover mechanism for driving the two groups of air monitors (2) to be turned over to the top of the clip-shaped shell (1) from the inside of the clip-shaped shell; the turnover mechanism enables the air monitor (2) to be positioned at the top of the clip-shaped shell (1) and keep a vertical state when monitoring air, and a flushing mechanism for cleaning the horizontal air monitor (2) is arranged on the inner side of the clip-shaped shell (1); the turnover mechanism enables the air monitor (2) to be in a horizontal state and matched with the flushing mechanism to clean the air monitor (2) when the air monitor (2) is stored inside the square-shaped shell (1).

3. The air quality monitoring method according to claim 2, characterized in that: a positioning hole (27) is formed in the outer surface of each air monitor (2), a plurality of second supporting plates (28) are fixedly connected to the inner side wall of the turnover plate (6), a positioning rod (29) is connected to the inner side of each second supporting plate (28) in a sliding mode, and the positioning rod (29) is used for being inserted into the positioning hole (27) to position the air monitor (2); a first baffle disc (30) is fixedly connected to the outer surface of each positioning rod (29), and a second spring (31) positioned between the first baffle disc (30) and the second supporting plate (28) is sleeved on the outer surface of each positioning rod (29); every equal fixedly connected with guide board (32) in locating lever (29), a plurality of extrusion swash plates (33) of fixedly connected with on the shape casing (1) inside wall of returning, extrusion swash plate (33) are used for extruding guide board (32) and make it move to the inboard and pull out locating hole (27) with locating lever (29).

4. The air quality monitoring method according to claim 2, characterized in that: a water outlet groove (34) is formed in the bottom of the clip-shaped shell (1), a water storage groove (35) is fixedly communicated with the bottom of the clip-shaped shell (1), and the water storage groove (35) is communicated with the water outlet groove (34); two groups of inclined guide blocks (36) which are positioned at the front side and the rear side of the water outlet groove (34) are fixedly connected to the bottom surface of the inner side of the clip-shaped shell (1), the inclined guide blocks (36) are used for guiding the cleaned water outlet groove (34) of the water tank, and an inclined plate (37) is fixedly connected to the outer surface of each sealing plate (12); the inclined plate (37) is connected to the inner side face of the inclined guide block (36) in a sliding mode, the sealing plate (12) is connected with the inclined guide block (36) in a sliding mode, and the inclined guide block (36) and the inclined plate (37) form a sealed guide inclined face together.

5. The air quality monitoring method according to claim 2, characterized in that: the top of the clip-shaped shell (1) penetrates through a plurality of second sliding rods (38) which are connected with the clip-shaped shell in a sliding mode, the top ends of the second sliding rods (38) are fixedly connected with a rectangular lifting plate (39) together, and a fourth spring (40) located between the rectangular lifting plate (39) and the clip-shaped shell (1) is sleeved on the outer surface of each second sliding rod (38).

6. The air quality monitoring method according to claim 2, characterized in that: the opening and closing mechanism comprises a plurality of groups of first air springs (7) with the same number as the air monitors (2), each group of first air springs (7) are fixedly connected to the inner top surface of the clip-shaped shell (1), and the bottoms of the same group of the first air springs (7) are fixedly connected with a U-shaped lifting frame (8); the left side wall and the right side wall inside each U-shaped lifting frame (8) are fixedly connected with a first extrusion block (9), the outer surface of each air monitor (2) is fixedly connected with an ejector rod (10), the ejector rods (10) are used for jacking the U-shaped lifting frames (8), the bottom of the clip-shaped shell (1) is provided with a plurality of through grooves (11) which are positioned right below the air monitors (2), and the through grooves (11) are used for the air monitors (2) to pass through when the air monitors (2) are turned over; two sealing plates (12) which are connected to the inner side wall of the clip-shaped shell (1) in a sliding mode are arranged above each through groove (11), a first sliding rod (13) is fixedly connected to the outer side wall of each sealing plate (12), and a first supporting block (14) is fixedly connected to the bottom surface inside the clip-shaped shell (1); the first sliding rods (13) penetrate through the first supporting blocks (14) and are in sliding connection with the first supporting blocks, and a first spring (15) fixedly connected between the sealing plate (12) and the first supporting blocks (14) is sleeved on the outer surface of each first sliding rod (13); the outer end of each first sliding rod (13) is fixedly connected with a second extrusion block (17) through a first connecting frame (16), and the second extrusion blocks (17) are used for acting with the first extrusion blocks (9).