CN221485392U

CN221485392U - River multi-element automatic monitoring system

Info

Publication number: CN221485392U
Application number: CN202323234624.3U
Authority: CN
Inventors: 丁润田; 张永宁; 李倩
Original assignee: Qingdao Hlk Environmental Automatic Control Engineering Co ltd
Current assignee: Qingdao Hlk Environmental Automatic Control Engineering Co ltd
Priority date: 2023-11-29
Filing date: 2023-11-29
Publication date: 2024-08-06
Anticipated expiration: 2033-11-29

Abstract

The utility model provides a river multi-element automatic monitoring system which comprises atmosphere monitoring equipment, water quality monitoring equipment, a power supply device and a control system and is characterized in that the control system comprises a control module, a data acquisition module, a wireless transmission module and a cloud server, wherein the data acquisition module is used for realizing data transmission through the wireless transmission module and the cloud server and storing monitoring data. The monitoring cabinet is internally provided with water quality monitoring equipment, an in-situ nutrient salt monitor and a flow cell, the flow cell is fixed at the lower part of the buoy through a variable-frequency submersible pump connected with a water conveying pipe and used for conveying a water sample to be detected into the flow cell, and the water quality monitoring equipment is arranged in the water sample to be detected in the flow cell. The system can perform unmanned on-line real-time monitoring on parameters such as water quality, nutrient salt, weather and the like, can meet the requirements of on-site debugging, checking and remote real-time checking of users, has comprehensive monitoring data and higher reliability and accuracy, and has good stability, safety and economy in operation of the monitoring system.

Description

River multi-element automatic monitoring system

Technical Field

The utility model belongs to the technical field of on-line monitoring of water environment and atmosphere, and particularly relates to an automatic river multi-element monitoring system.

Background

In order to further understand the comprehensive treatment conditions of the atmosphere and the water environment, the comprehensive treatment work of the atmosphere pollution and the water environment is continuously advanced, the quality of the atmosphere and the water environment is comprehensively improved, and a more comprehensive water environment and an atmosphere monitoring platform are needed. The traditional monitoring is only to independently monitor simple parameters such as temperature, conductivity, salinity, pH, dissolved oxygen and the like in the water environment, the monitoring of the parameters cannot be used for representing the quality of the water environment alone, more monitoring of various parameters such as turbidity, chlorophyll, blue-green algae, carbon dioxide, oil in water, ammonia nitrogen, nitrate nitrogen, nitrite nitrogen, phosphate, silicate, chemical oxygen demand and the like is needed, the comprehensive on-line monitoring of the water environment is realized, the existence of a corresponding water environment multi-element comprehensive monitoring station is needed, and the monitoring of the monitoring station with nutrient salt parameters is needed to be maintained regularly, so that a multi-element automatic monitoring station is generated.

With the prevalence of industrial pollution and dust pollution, atmospheric monitoring is imperative, and monitoring of parameters such as wind speed, wind direction, rainfall, visibility and the like is more and more important. The atmospheric monitoring and the water environment monitoring are required to be carried out simultaneously, the comprehensive monitoring of the water, the land and the air is realized, and the monitoring equipment is required to be integrated into a monitoring station, so that the comprehensive monitoring is realized.

In addition, the existing monitoring system is often arranged in a remote area or a reservoir of a valley or a canyon, and because communication and mains supply access are difficult, unmanned on-line real-time monitoring of parameters such as water quality, nutrient salt, weather and the like is difficult.

How to design a river multi-element automatic monitoring system, can carry out unmanned on-line real-time supervision to parameters such as quality of water, nutrient salt and weather, the monitoring data adopts two kinds of storage modes of local and long-range, can satisfy user's on-the-spot debugging, look over and long-range real-time demand of looking over to the monitoring data is comprehensive, and reliability and accuracy are higher, and monitoring system operation has good stability, security and economic nature. This is a technical problem to be solved in the art.

Disclosure of Invention

The utility model provides the river multi-element automatic monitoring system for solving the problems in the prior art, which can perform unattended online real-time monitoring on parameters such as water quality, nutrient salt, weather and the like, and the monitoring data adopts two storage modes of a local storage mode and a remote storage mode, so that the requirements of on-site debugging, checking and remote real-time checking of users can be met, and the monitoring data is comprehensive, higher in reliability and accuracy, and good in stability, safety and economical efficiency in operation.

The utility model aims at realizing the following technical scheme:

The river multi-element automatic monitoring system comprises an atmosphere monitoring device, a water quality monitoring device, a power supply device and a control system, wherein the control system comprises a control module, a data acquisition module and a wireless transmission module, the output ends of the atmosphere monitoring device and the water quality monitoring device are connected to the data acquisition module, the river multi-element automatic monitoring system is characterized in that the power supply device adopts a commercial power and wind-light complementary power generation and supply system, the control system comprises a cloud server, the control module is used for controlling and sending a test instruction, the data acquisition module is used for acquiring monitoring data and realizing data transmission with the cloud server through the wireless transmission module, the data acquisition module and the cloud server respectively store the monitoring data, and store and demonstrate at user mobile terminal, atmospheric monitoring equipment include weather appearance and visibility meter, water quality monitoring equipment include the water quality monitor, set up the nutritive salt switch board in the monitoring cabinet of monitoring system configuration water quality monitor and flow cell set up in the nutritive salt switch board normal position nutritive salt monitor, normal position nutritive salt monitor with data acquisition module connects, the flow cell passes through water intake piping connection the frequency conversion immersible pump outside the monitoring cabinet, the frequency conversion immersible pump with control system connects, the frequency conversion immersible pump is fixed in the lower part of a cursory, the water quality monitor sets up in the water sample that awaits measuring in the flow cell.

The improvement of the technical scheme is as follows: the control module and the data acquisition module are arranged in the integrated control box, the data acquisition module is arranged in the integrated control box, the weather instrument, the visibility meter and the video acquisition device are arranged on a weather installation frame, the weather installation frame is fixed on the monitoring cabinet, and the water quality monitor, the in-situ nutrient salt monitor, the weather instrument, the visibility meter and the video acquisition device are connected with the control module and the data acquisition module in the integrated control box through cables.

Further improvement of the technical scheme is as follows: set up frequency conversion refrigerator and pure water bucket and waste liquid bucket in the monitoring cabinet, normal position nutritive salt monitor is connected through pure water pipe and waste liquid pipe with pure water bucket and waste liquid bucket for collect waste liquid and pure water cleaning, frequency conversion refrigerator pass through the reagent pipe with normal position nutritive salt monitor is connected, frequency conversion refrigerator is used for depositing reagent and the standard liquid that nutritive salt test needs.

Further improvement of the technical scheme is as follows: the wind-solar complementary power generation and supply system comprises a wind-solar complementary installation frame, a solar panel, a storage battery, a battery box, wind power generation equipment and a wind-solar complementary controller, wherein the battery box is used for installing the storage battery and the wind-solar complementary controller, and the wind-solar complementary controller is connected with the control system.

Further improvement of the technical scheme is as follows: the side of monitoring cabinet sets up a plurality of jacks, the drain pipe that the flow cell is connected is followed the jack draws forth.

Further improvement of the technical scheme is as follows: the monitoring cabinet is provided with a cabinet air conditioner, and the monitoring cabinet is provided with an exhaust fan in an embedded mode.

Further improvement of the technical scheme is as follows: the bottom of monitoring cabinet sets up the installation base, set up the universal wheel on the bottom of installation base.

The utility model has the advantages and positive effects that:

1. The utility model adopts a double storage system to collect data, on one hand, the data can be stored in the data collection module, and the data is displayed in real time through the instrument display device, so that the on-site debugging and checking of a user are satisfied. On the other hand, the data is transmitted to a cloud server by adopting a wireless transmission system, a user can view the data in real time at any time and any place through a client such as a computer or a mobile phone, and the data can be put in a large screen in real time according to the requirements of the user, so that the data can be visually viewed on line;

2. The utility model adopts a commercial power and wind-light complementary power generation and supply system to provide various power supply guarantees, and solves the problem that the commercial power is inconvenient to erect in remote areas; when the utility model is used, under the condition of mains supply, the nutrient salt is provided with a small refrigerator device, and the reagent and the color developing agent are preserved at low temperature and constant temperature, so that the data error caused by the reagent and the color developing agent is greatly reduced, and the data accuracy is greatly improved;

3. The utility model adopts the variable-frequency submersible pump, is convenient for realizing digital control of flow speed and flow, is arranged on the buoyancy device to control the water sampling depth, and can collect the water sample with fixed water depth according to the requirement.

4. The nutrient salt control cabinet adopts the waste liquid recovery device to recover the reacted waste liquid, thereby avoiding secondary pollution to the environment;

5. The video acquisition device is provided, 360-degree dead-angle-free monitoring can be carried out on the periphery of the monitoring cabinet, unattended safety of outdoor arrangement is greatly improved, and videos can be checked and played back in real time through the display terminal;

6. The monitoring cabinet is provided with the universal wheels, so that the short-distance moving and transportation are convenient, and the universal wheels are removed if fixed installation is needed;

7. the monitoring cabinet adopts the cabinet air conditioner and the exhaust fan device to perform heat dissipation treatment on the instruments and the meters, thereby ensuring the normal operation of the instruments in a high-temperature state.

In summary, the utility model can perform unattended online real-time monitoring on parameters such as water quality, nutrient salt, weather and the like, the monitoring data adopts two storage modes of local and remote, the requirements of on-site debugging, checking and remote real-time checking of users can be met, the monitoring data is comprehensive, the reliability and the accuracy are higher, and the operation of the monitoring system has good stability, safety and economy.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the river multi-element automatic monitoring system of the present utility model;

FIG. 2 is a schematic view of the internal structure of a monitoring cabinet in the river multi-element automatic monitoring system of the utility model;

FIG. 3 is a left side view of a monitoring cabinet in the river multi-element automatic monitoring system of the present utility model;

FIG. 4 is a right side view of the monitoring cabinet in the river multi-element automatic monitoring system of the present utility model;

FIG. 5 is a rear view of the monitoring cabinet of the river multi-element automatic monitoring system of the present utility model;

FIG. 6 is a schematic view of a weather mounting in the river multi-element automatic monitoring system of the present utility model;

FIG. 7 is a schematic diagram of a wind-light complementary system in a river multi-element automatic monitoring system of the present utility model;

Fig. 8 is a schematic diagram of a pumping system in the river multi-element automatic monitoring system of the present utility model.

The numbers in the figures are: 1. the monitoring cabinet, 2, a cabinet air conditioner, 3, an exhaust fan, 4, a mounting base, 5, a weather mounting frame, 6, a weather instrument, 7, a video acquisition device, 8, a visibility meter, 9, a buoy, 10, a variable frequency submersible pump, 11, a water intake pipe, 12, a battery box, 13, a wind-solar complementary mounting frame, 14, a solar panel, 15, wind power generation equipment, 16, a lightning rod, 17, an integrated control box, 18, a water quality monitor, 19, an in-situ nutrient salt monitor, 20, a flow cell, 21 and a variable frequency refrigerator; 22. a pure water barrel and a waste liquid barrel; 23. a communication antenna; 24. a hoop; 25. a receptacle plate; 26. and a storage battery.

Detailed Description

The utility model is described in further detail below with reference to the accompanying drawings:

Referring to fig. 1-8, an embodiment of a river multi-element automatic monitoring system comprises an atmosphere monitoring device, a water quality monitoring device, a power supply device and a control system, wherein the control system comprises a control module, a data acquisition module and a wireless transmission module, the output ends of the atmosphere monitoring device and the water quality monitoring device are connected to the data acquisition module, the power supply device adopts a commercial power and wind-light complementary power generation power supply system, and the control system comprises a cloud server. The control module is used for controlling and sending a test instruction, the data acquisition module is used for acquiring monitoring data, the data transmission is realized by the wireless transmission module and the cloud server, the monitoring data are respectively stored by the data acquisition module and the cloud server, and the monitoring data are stored and displayed at the mobile terminal of the user. The atmosphere monitoring equipment comprises a weather instrument 6 and a visibility meter 8, and the water quality monitoring equipment comprises a water quality monitor 18. The monitoring cabinet 1 configured by the monitoring system is internally provided with a nutrient salt control cabinet, a water quality monitor 18 and a flow cell 20, the nutrient salt control cabinet is internally provided with an in-situ nutrient salt monitor 19, and the in-situ nutrient salt monitor 19 is connected with the data acquisition module. The flow-through cell 20 is connected with a variable-frequency submersible pump 10 outside the monitoring cabinet 1 through a water intake pipe 11, the variable-frequency submersible pump 10 is connected with the control system, the variable-frequency submersible pump 10 is fixed at the lower part of a buoy 9, and the water quality monitor 18 is arranged in a water sample to be detected in the flow-through cell 20.

The buoy 9 enables the variable-frequency submersible pump 10 to be always positioned at a designated water depth position; the variable frequency submersible pump 10 provides necessary power support for the water sample to be measured to enter the flow cell 20, and digital accurate control can be adopted for the flow when necessary.

The weather instrument 6 is used for monitoring parameters such as wind speed, wind direction, rainfall, air temperature, air pressure, humidity and the like; the visibility meter 8 is used for monitoring the visibility parameter.

In order to enhance the signal, a communication antenna 23 is arranged on the monitoring cabinet 1 and is used as an external antenna of the wireless transmission module.

Further, the control module and the data acquisition module are arranged in the integrated control box 17, the data acquisition module is arranged in the integrated control box 17, the weather instrument 6, the visibility meter 8 and the video acquisition device 7 are arranged on the weather mounting frame 5, the weather mounting frame 5 is fixed on the monitoring cabinet 1, and the weather mounting frame 5 is fixed on the back of the monitoring cabinet 1 through the anchor ear 24. The water quality monitor 18, the in-situ nutrient salt monitor 19, the weather instrument 6, the visibility meter 8 and the video acquisition device 7 are all connected with the control module and the data acquisition module in the integrated control box 17 through cables.

The video acquisition device 7 is used for acquiring video parameters, 360-degree dead-angle-free monitoring can be realized, video can be transmitted in real time and can be stored in a hard disk video recorder, and later viewing is facilitated.

Still further, the monitoring cabinet 1 is provided therein with a variable-frequency refrigerator 21, a pure water tank and a waste liquid tank 22, and the in-situ nutrient salt monitor 19 is connected with the pure water tank and the waste liquid tank 22 through pure water pipes and waste liquid pipes for collecting waste liquid and cleaning pure water. The variable-frequency refrigerator 21 is connected with the in-situ nutrient salt monitor 19 through a reagent pipe, and the variable-frequency refrigerator 21 is used for storing reagents and standard solutions required by nutrient salt test.

Specifically: the above-mentioned reagent and standard liquid that nutrient salt test needs are deposited in the frequency conversion refrigerator 21, can set up the optimum temperature of depositing, make reagent and reagent furthest preserve, reduce the reagent that the high temperature caused in summer and phenomenon such as freezing that cold winter caused, furthest guaranteed the degree of accuracy of data and the stability of test environment. The pure water bucket and the waste liquid bucket 22 are fixed at the bottom of the monitoring cabinet 1 and are used for storing pure water and waste liquid, when the in-situ nutrient salt monitor 19 is used for testing, the pure water is needed to be used for cleaning a pipeline and a reaction tank, and the pure water bucket of 25L is prepared and can be used for 2 months under normal conditions; the prepared waste liquid barrel is used for recycling toxic waste liquid, so that the pollution to the environment is reduced.

Still further, the wind-solar complementary power generation and supply system comprises a wind-solar complementary installation frame 13, a solar panel 14, a storage battery 26, a battery box 12, wind power generation equipment 15 and a wind-solar complementary controller, wherein the battery box 12 is used for installing the storage battery 26 and the wind-solar complementary controller, the wind-solar complementary controller is connected with the control system, and the storage battery 26 is used for storing wind energy and solar light energy. In order to ensure the safety of equipment, a lightning rod 16 is arranged at the upper end of the wind-solar complementary installation frame 13.

Still further, the side of the monitoring cabinet 1 is provided with a jack plate 25 with a plurality of jacks, the jacks comprise a power jack, a weather cable jack, a water inlet pipe jack, a water drain pipe jack and the like, and the water drain pipe connected with the flow cell 20 is led out from the water drain pipe jack on the jack plate 25.

The cabinet air conditioner 2 is arranged on the monitoring cabinet 1, and the exhaust fan 3 is embedded on the monitoring cabinet 1. The temperature of the equipment in the monitoring cabinet 1 can be reduced in summer, the liquid in the monitoring cabinet is prevented from being frozen by constant temperature in winter, measurement cannot be performed, and the equipment in the monitoring cabinet is ensured to be kept within constant temperature. In addition, exhaust fan 3 and cabinet air conditioner 2 collocation use are carried out the heat dissipation to equipment inside and are handled, also accessible inside and outside circulation lighten the inside medicament concentration of equipment, prevent that the poisonous liquid from volatilizing into gas through the high temperature, avoid causing personnel to hurt.

The bottom of the monitoring cabinet 1 is provided with a mounting base 4, and the bottom of the mounting base 4 is provided with universal wheels. The installation base 4 can facilitate the transportation and the installation of the cabinet body of the monitoring cabinet 1, and the universal wheels at the lower part facilitate the short-distance transportation, so that the problem of large-scale operation equipment required by the short-distance movement is solved. And if the universal wheel is required to be fixedly installed, the universal wheel is detached for installation.

The water quality monitor 18 provides water quality parameters such as temperature, conductivity, salinity, resistivity, TDS, dissolved oxygen, PH, turbidity, TSS, chlorophyll, oxidation-reduction potential, ammonia nitrogen, nitrate nitrogen, chloride and the like to a user, and is provided with a central cleaning brush for providing cleaning service for long-term monitoring of the optical sensor. When monitoring water quality, the variable-frequency submersible pump 10 conveys a water sample to be measured to the flow cell 20 through the water intake pipe 11, and the water quality monitor 18 is fixed in the water sample to be measured of the flow cell 20 through a buckle for measurement. After the water sample to be tested in the flow cell 20 is tested, the water is discharged through the water discharge pipe led out by the water discharge pipe jack of the jack plate 25 on the monitoring cabinet 1. And meanwhile, the control system sends the test data to a display terminal of a user through the data acquisition module and the wireless communication module.

The in-situ nutrient salt monitor 19 measures parameters of various nutrient salts such as ammonia nitrogen, nitrate nitrogen, nitrite nitrogen, phosphate, silicate and the like. When monitoring nutrient salts in water, the in-situ nutrient salt monitor 19 is connected with the pure water bucket and the waste liquid bucket 22 through pure water pipes and waste liquid pipes to collect waste liquid and clean pure water; is connected to the flow cell 20 through a water sampling tube, and is connected to the variable frequency refrigerator 21 through a reagent tube. After the monitoring is finished, the test data are sent to a display terminal of a user through the data acquisition module and the wireless communication module.

The integrated control box 17 is a control processing center of the whole system, and comprises a data acquisition module, a control module, a wireless communication module, a lightning protection module, a power module and the like. The control system in the integrated control box 17 can be configured as a computer, the upper computer sends instructions to the lower computer through the control module, and the lower computer receives the test instructions and transmits test data to the upper computer through the data acquisition module, so that the process is repeated. The data acquisition module stores the data in the local machine, transmits the data to the cloud server through the communication module, and stores and displays the data in the mobile terminal of the user.

The river multi-element automatic monitoring system disclosed by the utility model comprehensively utilizes modern various technological means to rapidly monitor the conditions of water environment and atmospheric environment in real time. Based on computer hardware, the system integrates various sensors on a platform, and performs signal acquisition through a data acquisition module, so that information is collected, analyzed and stored, and timely processing is facilitated when abnormal conditions occur. The utility model aims at the actual conditions and technical requirements of water environment and atmospheric environment, and considers the stability, reliability, accuracy, safety and running economy of the system and the instrument.

The utility model can realize real-time monitoring and automatic management of water resources and atmosphere, master water quality parameters such as water temperature, conductivity, salinity, total dissolved solids, PH value, dissolved oxygen, turbidity, chlorophyll, blue-green algae, water level, oil in water, ammonia nitrogen, nitrate nitrogen, nitrite nitrogen, phosphate, silicate, chemical oxygen demand and the like, and weather information such as wind speed, wind direction, air temperature, air pressure, humidity, rainfall, visibility and the like at any time, and provide timely and comprehensive data support for water environment and weather monitoring and protecting work.

The river multi-element automatic monitoring system is suitable for various severe sites. Basically, the terminal can be ensured to be always on line, the commercial power and wind-solar complementary power generation is adopted, the cost investment and difficult processing which are required to be solved by the field commercial power are solved, the video acquisition device 7 is adopted to realize 360-degree dead angle-free monitoring, and the safety of field distribution is solved.

It should be understood that the above description is not intended to limit the utility model to the particular embodiments disclosed, but to limit the utility model to the particular embodiments disclosed, and that various changes, modifications, additions and substitutions can be made herein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims

1. The river multi-element automatic monitoring system comprises an atmosphere monitoring device, a water quality monitoring device, a power supply device and a control system, wherein the control system comprises a control module, a data acquisition module and a wireless transmission module, the output ends of the atmosphere monitoring device and the water quality monitoring device are connected to the data acquisition module, the river multi-element automatic monitoring system is characterized in that the power supply device adopts a commercial power and wind-light complementary power generation and supply system, the control system comprises a cloud server, the control module is used for controlling and sending a test instruction, the data acquisition module is used for acquiring monitoring data and realizing data transmission with the cloud server through the wireless transmission module, the data acquisition module and the cloud server respectively store the monitoring data, and store and demonstrate at user mobile terminal, atmospheric monitoring equipment include weather appearance and visibility meter, water quality monitoring equipment include the water quality monitor, set up the nutritive salt switch board in the monitoring cabinet of monitoring system configuration water quality monitor and flow cell set up in the nutritive salt switch board normal position nutritive salt monitor, normal position nutritive salt monitor with data acquisition module connects, the flow cell passes through water intake piping connection the frequency conversion immersible pump outside the monitoring cabinet, the frequency conversion immersible pump with control system connects, the frequency conversion immersible pump is fixed in the lower part of a cursory, the water quality monitor sets up in the water sample that awaits measuring in the flow cell.

2. The river multi-element automatic monitoring system according to claim 1, wherein the control module and the data acquisition module are arranged in an integrated control box, the data acquisition module is arranged in the integrated control box, the weather instrument, the visibility meter and the video acquisition device are arranged on a weather mounting frame, the weather mounting frame is fixed on the monitoring cabinet, and the water quality monitor, the in-situ nutrient salt monitor, the weather instrument, the visibility meter and the video acquisition device are all connected with the control module and the data acquisition module in the integrated control box through cables.

3. The river multi-element automatic monitoring system according to claim 1 or 2, wherein a variable-frequency refrigerator, a pure water barrel and a waste liquid barrel are arranged in the monitoring cabinet, the in-situ nutrient salt monitor is connected with the pure water barrel and the waste liquid barrel through pure water pipes and waste liquid pipes and is used for collecting waste liquid and cleaning pure water, the variable-frequency refrigerator is connected with the in-situ nutrient salt monitor through a reagent pipe and is used for storing reagents and standard liquids required by nutrient salt tests.

4. The river multi-element automatic monitoring system according to claim 1 or 2, wherein the wind-solar complementary power generation and supply system comprises a wind-solar complementary mounting frame, a solar panel, a storage battery, a battery box, wind power generation equipment and a wind-solar complementary controller, wherein the battery box is used for mounting the storage battery and the wind-solar complementary controller, and the wind-solar complementary controller is connected with the control system.

5. The river multi-element automatic monitoring system according to claim 3, wherein the wind-solar complementary power generation and supply system comprises a wind-solar complementary mounting frame, a solar panel, a storage battery, a battery box, wind power generation equipment and a wind-solar complementary controller, wherein the battery box is used for mounting the storage battery and the wind-solar complementary controller, and the wind-solar complementary controller is connected with the control system.

6. The river multi-element automatic monitoring system according to claim 1 or 2, wherein a plurality of insertion holes are formed in the side face of the monitoring cabinet, and a drain pipe connected with the flow cell is led out of the insertion holes.

7. The river multi-element automatic monitoring system according to claim 5, wherein a plurality of jacks are arranged on the side face of the monitoring cabinet, and a drain pipe connected with the flow cell is led out of the jacks.

8. The river multi-element automatic monitoring system according to claim 1 or 2, wherein a cabinet air conditioner is arranged on the monitoring cabinet, and an exhaust fan is arranged on the monitoring cabinet in an embedded mode.

9. The river multi-element automatic monitoring system according to claim 7, wherein a cabinet air conditioner is arranged on the monitoring cabinet, and an exhaust fan is arranged on the monitoring cabinet in an embedded mode.

10. The river multi-element automatic monitoring system according to claim 1 or 2, wherein a mounting base is arranged at the bottom of the monitoring cabinet, and universal wheels are arranged on the bottom of the mounting base.