CN216979008U - Air quality continuous monitoring system - Google Patents

Abstract

The utility model provides an air quality continuous monitoring system which comprises a cabinet body, a front door plate, a rear door plate, a storage rack, a monitor and an air circulation assembly, wherein the front door plate is rotatably connected with the cabinet body; the rear door plate is rotatably connected to the cabinet body and is positioned on the opposite side of the front door plate; the article placing rack is arranged in the cabinet body and is provided with a plurality of article placing spaces which are communicated in the front-back direction; the monitor is arranged in the object placing space and is provided with a monitoring head extending out of the cabinet body, the air circulation assembly is fixedly arranged in the cabinet body and is provided with an air inlet and an air outlet which are vertically distributed in the cabinet body. According to the air quality continuous monitoring system provided by the utility model, the air circulation assembly is arranged in the cabinet body, and the air inlet and the air outlet which are vertically distributed are used for ensuring the uniform temperature in the cabinet body, effectively avoiding the overheating damage of the monitor and prolonging the service life of the monitor.

Description

Air quality continuous monitoring system

Technical Field

The utility model belongs to the technical field of cabinets, and particularly relates to an air quality continuous monitoring system.

Background

Pollutants in the air, such as sulfur dioxide (SO)₂) Nitrogen dioxide (NO)₂) Carbon monoxide (CO), ozone (O)₃) The presence of particulate matter PM2.5, particulate matter PM10, etc., can affect the health of a person when the concentration exceeds the standard. The existing air quality monitoring system arranged outside carries out real-time monitoring, so that each pollutant data in the atmosphere is obtained, the excellent grade of the air quality in the existing environment is obtained by analyzing the verticality of each pollutant, and the air can be treated in a targeted manner or corresponding optimization means are adopted.

Because mainly be to the pollutant in the atmosphere analysis, then air quality monitoring system's main operational environment is in the external world, its inside equipment is more, when using under the environment of more sweltering (like summer), the steam that inside equipment heat dissipation produced is because the temperature is high, density is big, can be in the top in the device, and then make the upper air temperature in the air quality monitoring system higher, lower floor air temperature is lower, inside temperature is inhomogeneous and then the influence is in the device heat dissipation of top in the device, serious then can cause the overheated damage of equipment.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides an air quality continuous monitoring system, aiming at prolonging the service life of an internal monitor on the basis of heat insulation and preventing external rainwater and the like from entering the internal monitor to damage the internal monitor.

In order to achieve the purpose, the utility model adopts the technical scheme that: there is provided a continuous air quality monitoring system comprising:

a cabinet body;

the front door plate is rotatably connected to the cabinet body;

the rear door plate is rotatably connected to the cabinet body and is positioned on the opposite side of the front door plate;

the storage rack is arranged in the cabinet body and is provided with a plurality of storage spaces which are communicated in the front-back direction;

the monitor is arranged in the storage space and is provided with a monitoring head extending out of the cabinet body; and

and the air circulation component is fixedly arranged in the cabinet body and is provided with an air inlet and an air outlet which are vertically distributed in the cabinet body.

In one possible implementation, the air circulation assembly includes:

the air duct is fixedly arranged on the inner wall of the cabinet body and extends along the vertical direction, and the two ends of the air duct form the air inlet and the air outlet respectively; and

and the fan is arranged in the air channel and used for guiding the gas in the air channel.

In one possible implementation, the shelf comprises:

the fixing frame is fixedly arranged in the cabinet body; and

the bearing plates are arranged in the vertical direction, the bearing plates are detachably connected with the fixing frame and are adjacent to each other, and the bearing plates are distributed at intervals to form the object placing space.

In some embodiments, the fixing frame has a first side surface and a second side surface which are adjacent to each other, the first side surface and the second side surface are vertically arranged, the first side surface is provided with a plurality of first mounting holes from top to bottom, and the first mounting holes are used for fixing the supporting plate;

the second side faces the front door plate or the rear door plate, a plurality of third mounting holes are formed in the second side faces from top to bottom, and the third mounting holes are used for fixing the monitor.

In some embodiments, the monitor is provided with end plates on two opposite sides of the front end surface, and the end plates are used for abutting against the second side surface and being connected with the third mounting holes through fasteners.

In a possible implementation manner, the end face of the monitor is also provided with a handle.

In a possible implementation manner, the air quality continuous monitoring system further comprises an industrial control device, a fixing frame used for installing the industrial control device is arranged on the inner side of the front door panel or the inner side of the rear door panel, and a water retaining strip is further arranged above the fixing frame.

In a possible implementation manner, a waterproof platform is arranged on the top of the cabinet in a protruding mode and provided with a through hole for the monitoring head to penetrate through.

In one possible implementation, the continuous air quality monitoring system further includes a cooling device installed inside the cabinet, the cooling device includes:

the mounting shell is fixedly arranged inside the cabinet body, and an observation window is arranged on the mounting shell; and

the air conditioner is arranged in the installation shell, and an operation button on the air conditioner corresponds to the observation window.

In some embodiments, a diversion cover is installed on a side wall of the installation shell, the diversion cover encloses to form a first cavity communicated with the cabinet body and a second cavity communicated with the outside, an air supply outlet of the air conditioner is communicated with the first cavity, and an air exhaust outlet is communicated with the second cavity.

In the embodiment of the application, compare with prior art, in the in-service use, will measure the monitor that corresponds required data and install to putting the object space in, and the monitoring head of monitor stretches out in the outside of the cabinet body, realizes the continuous monitoring to air parameter etc. door plant before opening or open the back door plant and all can carry out loading and unloading operation to the monitor. According to the air quality continuous monitoring system, the air circulation assembly is arranged in the cabinet body, and the air inlets and the air outlets which are vertically distributed are used for enabling air at the top and air at the top in the cabinet body to circulate, such as upward conveying of cold air at the bottom or downward conveying of hot air at the top, so that the temperature approximation of different heights in the cabinet body is achieved, the temperature uniformity is guaranteed, and overheating damage of a monitor caused by overheating of a certain height in the cabinet body is prevented. The excessive temperature difference between the top and the bottom is prevented, so that the influence on the work of the monitor is avoided, the overheating damage of the monitor is effectively avoided, and the service life of the monitor is prolonged.

Drawings

Fig. 1 is a schematic perspective view of an air quality continuous monitoring system according to an embodiment of the present invention (only a front door panel is in an open state);

fig. 2 is a schematic perspective view of a cabinet body according to an embodiment of the present invention;

fig. 3 is a schematic perspective view of a second cabinet body according to an embodiment of the present invention;

fig. 4 is a schematic three-dimensional structure diagram of a cabinet body adopted in the embodiment of the utility model.

Description of reference numerals:

10-a cabinet body; 11-waterproof bosses; 12-a fixing frame; 13-water retaining strip; 14-edge warping;

20-a front door panel;

30-rear door panel;

40-a shelf; 41-a fixed frame; 411 — first mounting hole; 412-a third mounting hole; 42-a support plate; 421-a vent; 422-second mounting hole; 423-mounting plate;

50-an insulating layer;

60-fixing the cover;

70-a cooling device; 71-mounting the housing; 72-air conditioning; 73-observation window; 74-a flow diversion cover;

80-a monitor; 81-monitoring head; 82-industrial control equipment; 83-end plate; 84-a handle;

90-an air circulation assembly; 91-an air duct; 92-Fan.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and do not limit the utility model.

Referring to fig. 1 to 4, the air quality continuous monitoring system provided by the present invention will now be described. The continuous air quality monitoring system comprises a cabinet body 10, a front door panel 20, a rear door panel 30, a shelf 40, a monitor 80 and an air circulation assembly 90, wherein the front door panel 20 is rotatably connected to the cabinet body 10; the rear door panel 30 is rotatably connected to the cabinet 10 and is positioned at the opposite side of the front door panel 20; the shelf 40 is arranged in the cabinet body 10, and the shelf 40 is provided with a plurality of storage spaces which are penetrated along the front-back direction; the monitor 80 is arranged in the storage space and is provided with a monitoring head 81 extending out of the cabinet body 10; the air circulation assembly 90 is fixedly disposed in the cabinet 10 and has an air inlet and an air outlet distributed up and down in the cabinet 10.

It should be noted that, the air inlet and the air outlet in the cabinet 10 may be an air inlet at the top and an air outlet at the bottom; the top part can be an air outlet, and the bottom part can be an air inlet. In a word, the air inlet and the air outlet are distributed up and down, and the air in the cabinet body 10 can flow up and down circularly.

Specifically, the monitor 80 can be a particulate matter monitor, and can be divided into a PM2.5 particulate matter monitor and a PM10 particulate matter monitor, the monitoring head 81 corresponding to the PM2.5 particulate matter monitor is a PM2.5 particulate matter cutter, and the monitoring head 81 corresponding to the PM10 particulate matter monitor is a PM10 particulate matter cutter; the monitor 80 may also be an air quality monitor, and the monitoring head 81 corresponding to the air quality monitor is an air sampling rod or the like. The type and number of monitors 80 installed in the cabinet 10 are not fixed, and can be assembled according to the required data in actual measurement.

Compared with the prior art, the air quality continuous monitoring system provided by the embodiment has the advantages that in the actual use process, the monitor 80 capable of measuring corresponding required data is installed in the storage space, the monitoring head 81 of the monitor 80 extends out of the cabinet body 10, continuous monitoring of air parameters and the like is achieved, and the monitor can be assembled and disassembled by opening the front door plate 20 or opening the rear door plate 30. According to the air quality continuous monitoring system, the air circulation assembly 90 is arranged in the cabinet body, and the air inlets and the air outlets which are vertically distributed are used for enabling air at the top and air at the top in the cabinet body 10 to circulate, such as cold air at the bottom is conveyed upwards or hot air at the top is conveyed downwards, so that the temperature approximation of different heights in the cabinet body 10 is realized, the temperature uniformity is guaranteed, and the monitor 80 is prevented from being damaged due to overheating at a certain height in the cabinet body 10. The influence on the work of the monitor 80 due to the overlarge temperature difference between the top and the bottom is prevented, the overheat damage of the monitor 80 is effectively avoided, and the service life of the monitor 80 is prolonged.

In some embodiments, one embodiment of the air circulation assembly 90 described above may be configured as shown in FIG. 4. Referring to fig. 4, the air circulation assembly 90 includes an air duct 91 and a fan 92, the air duct 91 is fixedly disposed on an inner wall of the cabinet 10 and extends in an up-and-down direction, and an air inlet and an air outlet are respectively formed at two ends of the air duct 91; the fan 92 is disposed in the air duct 91 and is used for guiding air in the air duct 91. When the monitor 80 in the cabinet 10 works, the fan 92 is turned on, and under the work of the fan 92, the air at the air inlet in the air duct 91 flows to the air outlet, so that the circulation of the air at the top and the bottom in the cabinet 10 is realized, the circulation rate of the air is promoted by arranging the fan 92, and the cooling efficiency is improved.

In some embodiments, a specific embodiment of the above-mentioned shelf 40 can be configured as shown in fig. 2. Referring to fig. 2, the storage rack 40 includes a fixing frame 41 and a supporting plate 42, wherein the fixing frame 41 is fixedly arranged in the cabinet 10; the plurality of support plates 42 are arranged along the vertical direction, the support plates 42 are detachably connected with the fixed frame 41, and the adjacent support plates 42 are distributed at intervals to form an object placing space. In fact, not only the space between two adjacent support plates 42 can form a storage space, but also the monitor 80 can be mounted on the uppermost support plate 42, and actually, one monitor 80 can be placed on each support plate 42.

The support plates 42 are detachably connected with the fixed frame 41, and the number of the storage space can be adjusted by detaching the support plates 42, for example, the fixed frame 41 is provided with 5 installation positions of the support plates 42, but only 4 support plates 42 are installed, so that at most 4 monitors 80 can be installed, and the installation number of the monitors 80 can be conveniently adjusted.

In some embodiments, a modified embodiment of the support plate 42 described above may be configured as shown in FIG. 2. Referring to fig. 2, the support plate 42 is provided with a vent hole 421. The ventilation holes 421 are formed in the supporting plate 42, so that air circulation in the vertical direction in the cabinet body 10 is facilitated, the temperature balance of each height in the space in the cabinet body 10 is further ensured, and the monitor 80 at the position is prevented from being damaged due to overheating caused by local overheating; in addition, when the cabinet body 10 is internally provided with a plurality of monitors 80, each monitor 80 needs to be correspondingly connected with a power supply, the vent holes 421 can also be used as functional holes for fixing a patch board, the functionality is stronger, the internal wiring is convenient, and the orderly wiring of each power line in the cabinet body 10 is ensured.

In some embodiments, a specific connection manner of the fixing frame 41 and the support plate 42 can be as shown in fig. 1 to 2 and 4. Referring to fig. 1 to 2 and 4, the fixing frame 41 has a first side surface and a second side surface which are adjacent to each other, the first side surface and the second side surface are vertically arranged, the first side surface is provided with a plurality of first mounting holes 411 from top to bottom, and the first mounting holes 411 are used for fixing the supporting plate 42; the second side faces the front door panel 20 or the rear door panel 30, and the second side is provided with a plurality of third mounting holes 412 from top to bottom, and the third mounting holes 412 are used for fixing the monitor 80. After the monitor 80 is placed in the storage space, the monitor 80 can be connected and fixed (the monitor can be connected through fasteners such as bolts) with the third mounting hole 412 on the fixed frame 41, so that the mounting stability of the monitor 80 is improved; similarly, the supporting plate 42 and the fixing frame 41 can be connected to the first mounting hole 411 by a fastener such as a bolt, which facilitates the detachment and replacement of the supporting plate 42.

It should be noted that the number of the first mounting holes 411 on the first side surface is much larger than the number of the support plates 42 to be mounted, for example, the first mounting holes 411 are provided with 20 groups from top to bottom, each group can be correspondingly mounted with one support plate 42, and a plurality of groups of first mounting holes 411 can be spaced between adjacent support plates 42, so that the mounting number of the support plates 42 can be freely changed, the spacing is different after the mounting of different support plates 42, and the height of the storage space can be flexibly adjusted, thereby being suitable for the mounting of different types of monitors 80.

Specifically, the edge of the supporting plate 42 is provided with a mounting plate 423 perpendicular to the plate surface, the mounting plate 423 is provided with a second mounting hole 422 corresponding to the first mounting hole 411, and a threaded fastener is connected between the first mounting hole 411 and the second mounting hole 422. Through set up mounting panel 423 on bearing board 42, improve bearing board 42's joint strength, and then guarantee its bearing stability to monitor 80, prevent that monitor 80 from dropping.

In some embodiments, a modified embodiment of the continuous air quality monitoring system described above may be configured as shown in fig. 2. Referring to fig. 2, the side walls and the top of the cabinet 10, the front door panel 20 and the rear door panel 30 are respectively provided with an insulating layer 50. The heat insulation layer 50 is arranged, so that the monitor can be prevented from being damaged due to overheating caused by overhigh temperature in the cabinet body 10 under a hot condition; the normal opening of the monitor 80 can be prevented from being influenced by the supercooling inside the cabinet 10 under the cold condition; thereby protecting the monitor 80 inside and prolonging the service life of the monitor 80; the heat insulation layer 50 disposed on the top of the cabinet 10 can also play a role of sun protection, so as to prevent the temperature from rising in the cabinet 10 due to insolation.

In some embodiments, an improved implementation of the continuous air quality monitoring system described above may be configured as shown in fig. 1-2. Referring to fig. 1 to 2, the air quality continuous monitoring system further includes a fixing cover 60, and the fixing cover 60 is detachably connected to the cabinet 10, the front door panel 20, or the rear door panel 30 and covers the periphery of the insulating layer 50. When the fixing cover 60 is arranged on the front door panel 20, the fixing cover 60 is buckled on the panel surface of the front door panel 20 and forms a closed space with the panel surface of the front door panel 20, and the heat-insulating layer 50 is arranged in the closed space; similarly, the same applies to the case where the fixed cover 60 is provided on the rear door panel 30 and the cabinet 10. Through the fixed cover 60 of detachable setting, conveniently install heat preservation 50, after using suitable time, can change ageing heat preservation 50.

Specifically, the heat insulating layer 50 may be formed by placing heat insulating foam, gas having poor heat conductivity, or the like in an enclosed space formed by the fixing cover 60 and the front door panel 20, the rear door panel 30, and the side wall or the top of the cabinet 10.

In some embodiments, a modified implementation of the monitor 80 described above may be configured as shown in FIG. 1. Referring to fig. 1, the monitor 80 has end plates 83 at two opposite sides of the front surface, and the end plates 83 are used to abut against the second side surface and are connected to the third mounting holes by fasteners. Through setting up end plate 83, when putting into object space with monitor 80, when end plate 83 butt second side, then monitor 80 position is confirmed and is installed the fastener afterwards and fix, makes things convenient for monitor 80's installation, reduces intensity of labour.

In some embodiments, a modified implementation of the monitor 80 described above may be configured as shown in FIG. 1. Referring to fig. 1, the monitor 80 is also provided with a handle 84 at its end face. The monitor 80 is generally heavier, and the monitor 80 can be put in and taken out through the handle 84 during installation or disassembly, so that the operation is more flexible.

In some embodiments, an improved implementation of the continuous air quality monitoring system described above may be configured as shown in fig. 1-2. Referring to fig. 1 to 2, the air quality continuous monitoring system further includes an industrial control device 82, a fixing frame 12 for installing the industrial control device 80 is disposed on the inner side of the front door panel 20 or the rear door panel 30, and a water bar 13 is disposed above the fixing frame 12. The industrial control device 82 is mainly used for being electrically connected with the monitors 80 inside the cabinet 10, so that when the front door panel 20 or the rear door panel 30 is opened, various measured data values can be directly observed on the industrial control device 82, the industrial control device 82 comprises a display screen, a keyboard, a mouse and the like, and the fixing frame 12 is fixed on the industrial control device, so that the operation is convenient. Because the heat insulation layers 50 are required to be arranged on the front door panel 20 and the rear door panel 30, the thickness of the front door panel 20 or the rear door panel 30 is thick, water is easy to store on the top, when the front door panel 20 or the rear door panel 30 is opened, the stored water can flow to the inner side of the front door panel 20 or the rear door panel 30 due to inertia, and damage can be caused if the stored water falls onto the industrial control equipment 82; through setting up water bar 13, the water storage drops to water bar 13 owing to inertia, and then protects industrial control equipment 82, prevents to damage the back replacement cost increase.

It should be noted that, when the fixing frame 12 is disposed on the front door panel 20, the water bar 13 is also disposed on the front door panel 20 and above the fixing frame 12; when the fixed frame 12 is arranged on the rear door panel 30, the water bar 13 is also arranged on the rear door panel 30 and is positioned above the fixed frame 12; the water bar 13 and the fixing frame 12 are not directly connected in the above two modes. The other is that the water bar 13 is directly connected with the fixed frame 12 and is positioned above the fixed frame 12.

Specifically, the fixing frame 12 may be fixed on the front door panel 20 or the rear door panel 30 by bolts, and two placing slots with openings are formed, and the keyboard and the mouse can be easily clamped into the placing slots and are conveniently taken out; because the operation is mainly performed through the mouse and the keyboard, the display screen can be directly fixed.

In some embodiments, a modified implementation of the continuous air quality monitoring system described above may be configured as shown in fig. 2. Referring to fig. 2, a first side of the water bar 13 is fixedly connected with the front door panel 20 or the rear door panel 30, and a second side of the water bar 13 is upwardly warped to form a warped edge 14, and the second side is the opposite side of the first side. When the stored water on the front door panel 20 or the rear door panel 30 flows into the water bar 13, in order to prevent the stored water from flowing down from the water bar 13 due to overlarge inertia, the width of the water bar 13 needs to be larger, the stored water can be blocked at the second side of the water bar 13 to continue flowing by arranging the raised edge 14, and the water can be effectively retained at the top of the fixing frame 12; the water bar 13 does not need to be provided with too wide width, and the used materials are correspondingly reduced.

In some embodiments, an improved embodiment of the cabinet 10 may be configured as shown in fig. 1-3. Referring to fig. 1 to 3, a waterproof platform 11 is convexly disposed on the top of the cabinet 10, and the waterproof platform 11 has a through hole for the monitoring head 81 to pass through. When meetting the environment of rain, the top of the cabinet body 10 can produce ponding, does not set up under the condition of waterproof boss 11, can lead to ponding to flow into in the cabinet body 10, through setting up waterproof boss 11, ponding can only stop at the top of the cabinet body 10, prevents to get into inside the cabinet body 10, and then protects inside circuit and monitor 80.

In some embodiments, a modified implementation of the continuous air quality monitoring system described above may be configured as shown in fig. 3. Referring to fig. 3, the air quality continuous monitoring system further includes a cooling device 70 installed inside the cabinet 10, the cooling device 70 includes an installation casing 71 and an air conditioner 72, the installation casing 71 is fixedly installed inside the cabinet 10, and an observation window 73 is arranged on the installation casing 71; the air conditioner 72 is provided in the mounting case 71, and manipulation buttons on the air conditioner 72 correspond to the observation windows 73. Preferably, the air conditioner 72 is an industrial air conditioner, and when the weather is hot, the environment inside the cabinet 10 can be cooled through the air conditioner 72; when the weather is cold, the air conditioner 72 can supply heat to the environment inside the cabinet 10 to prevent the monitor from working normally due to overheating or overcooling of the environment inside the cabinet 10; wherein, the installation shell 71 is provided with an observation window 73, and the working state of the air conditioner 72 can be debugged through the observation window 73, such as changing the working temperature or the working mode.

In some embodiments, a specific implementation of the mounting housing 71 described above may be configured as shown in FIG. 3. Referring to fig. 3, a diversion cover 74 is installed on a side wall of the installation casing 71, the diversion cover 74 encloses to form a first cavity communicated with the inside of the cabinet 10 and a second cavity communicated with the outside, an air supply outlet of the air conditioner 72 is communicated with the first cavity, and an air exhaust outlet is communicated with the second cavity. For example, when the air conditioner 72 is used for cooling, the cold air of the air conditioner 72 enters the cabinet 10 by arranging the diversion cover 74, and the air outlet of the air conditioner 72 is mainly hot air and is output to the outside; similarly, when the air conditioner 72 heats, hot air enters the cabinet 10, and the air at the air outlet is output to the outside, so that the cold and hot air flow of the air conditioner 72 is accurately guided, and the heating or cooling effect is optimized.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. An air quality continuous monitoring system, comprising:

a cabinet body;

the front door plate is rotatably connected to the cabinet body;

the rear door plate is rotatably connected with the cabinet body and is positioned on the opposite side of the front door plate;

the storage rack is arranged in the cabinet body and is provided with a plurality of storage spaces which are communicated in the front-back direction;

the monitor is arranged in the storage space and is provided with a monitoring head extending out of the cabinet body; and

and the air circulation component is fixedly arranged in the cabinet body and is provided with an air inlet and an air outlet which are vertically distributed in the cabinet body.

2. The air quality continuous monitoring system of claim 1, wherein the air circulation assembly comprises:

the air duct is fixedly arranged on the inner wall of the cabinet body and extends along the vertical direction, and the air inlet and the air outlet are formed at two ends of the air duct respectively; and

and the fan is arranged in the air channel and used for guiding the gas in the air channel.

3. The continuous air quality monitoring system of claim 1, wherein the shelf comprises:

the fixing frame is fixedly arranged in the cabinet body; and

the bearing plates are arranged in the vertical direction, the bearing plates are detachably connected with the fixing frame and are adjacent to each other, and the bearing plates are distributed at intervals to form the object placing space.

4. The continuous air quality monitoring system according to claim 3, wherein the fixing frame has a first side surface and a second side surface which are adjacent to each other, the first side surface and the second side surface are arranged vertically, the first side surface is provided with a plurality of first mounting holes from top to bottom, and the first mounting holes are used for fixing the supporting plate;

the second side faces the front door plate or the rear door plate, a plurality of third mounting holes are formed in the second side faces from top to bottom, and the third mounting holes are used for fixing the monitor.

5. The air quality continuous monitoring system of claim 4, wherein the monitor has end plates on opposite sides of a front face thereof, the end plates adapted to abut the second side face and to be connected to the third mounting holes by fasteners.

6. The continuous air quality monitoring system of claim 1, wherein the monitor further comprises a handle on an end face of the monitor.

7. The air quality continuous monitoring system according to claim 1, further comprising industrial control equipment, wherein a fixing frame for installing the industrial control equipment is arranged on the inner side of the front door panel or the rear door panel, and a water bar is further arranged above the fixing frame.

8. The air quality continuous monitoring system according to claim 1, wherein a waterproof platform is convexly arranged on the top of the cabinet body, and the waterproof platform is provided with a through hole for the monitoring head to penetrate through.

9. A continuous air quality monitoring system according to claim 1, further comprising a cooling device mounted inside the cabinet, the cooling device comprising:

the mounting shell is fixedly arranged inside the cabinet body, and an observation window is arranged on the mounting shell; and

the air conditioner is arranged in the installation shell, and an operation button on the air conditioner corresponds to the observation window.

10. The air quality continuous monitoring system according to claim 9, wherein a shunt cover is installed on a side wall of the installation shell, the shunt cover encloses a first cavity communicated with the cabinet body and a second cavity communicated with the outside, a supply air outlet of the air conditioner is communicated with the first cavity, and an exhaust air outlet is communicated with the second cavity.

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