CN116823135A - Management method and device based on intelligent park - Google Patents

Abstract

The application provides a management method and equipment based on an intelligent park, comprising the following steps: collecting environmental parameters in an intelligent park and running state parameters of equipment in the park; calling corresponding data as a control command according to the data calling command, sending the control command to corresponding in-park equipment, and analyzing and processing the acquired data acquired from the in-park equipment; and displaying the data analyzed and processed by the central processing unit. The application establishes a complete model for the park, establishes complete comprehensive security, space management and energy efficiency management, combines intelligent equipment, and enables the park energy efficiency to be controllable, visual and controllable by an informatization means.

Description

Management method and device based on intelligent park

Technical Field

The application relates to the technical monitoring field, in particular to a management method and device based on an intelligent park.

Background

The park (e.g. intelligent park) management in the prior art usually adopts a manual inspection mode or a mode of monitoring by a fixed camera device to identify and discover target behaviors, wherein the target behaviors are such as high-altitude parabolic objects, tread greening and the like. However, the prior art lacks comprehensive technical management means, can not realize manageability, visibility and controllability at the same time, and has the problem that the target behavior is difficult to discover and trace to the source in time.

Disclosure of Invention

Aiming at the defects in the prior art, the application aims to provide a management method and equipment based on an intelligent park.

According to the application, the management equipment based on the intelligent park comprises:

acquisition equipment: collecting environmental parameters in an intelligent park and running state parameters of equipment in the park; the acquisition equipment comprises a dynamic monitoring module and a static monitoring module, wherein the dynamic monitoring module is used for acquiring and monitoring parameters of the external environment of each road, greening and building in the intelligent park, and the static monitoring module is used for monitoring parameters of electric facilities of the intelligent park through each data sensor;

and the central processing unit: calling corresponding data as a control command according to the data calling command, sending the control command to corresponding in-park equipment, and analyzing and processing the acquired data acquired from the in-park equipment;

and (3) a management platform: and displaying the data analyzed and processed by the central processing unit.

Preferably, the management platform includes:

model module: simulation modeling is carried out according to the design data of the intelligent park to obtain a model, and the acquired data processed by the central processing unit is displayed at the corresponding position of the model;

display device: displaying parameters and models;

an alarm module: comparing the data processed by the central processing unit with modeling standard data, and sending out an alarm after the comparison result indicates that the abnormality occurs;

the execution module: various electric facilities and auxiliary equipment in the intelligent park are started and stopped according to the alarm.

Preferably, the method further comprises:

operation management module: and carrying out display management on the building, security and energy efficiency in the intelligent park.

Preferably, the operation management module includes:

and the comprehensive security module is used for: and setting up an electronic fence at the peripheral boundary of the intelligent park, calling a dynamic detection module and a static detection module to detect the target behavior of the invasive electronic fence, and issuing a task work order according to the operation input of a commander, wherein the task work order guides security personnel to navigate in place.

Preferably, the operation management module includes:

and a space management module: establishing a complete intelligent park building model and room information, displaying intelligent park quotations, and sharing service information in real time;

and the energy efficiency management module is used for: the water power monitoring, air conditioning monitoring, illumination monitoring, trend analysis and energy efficiency diagnosis are carried out, the water power, air conditioning and illumination of the intelligent park are monitored in real time, the outdoor environment of the intelligent park is monitored, the quality of the environment around the intelligent park is assessed by collecting various values, the environment temperature is monitored in real time, the alarm is given in real time under the condition of abnormal temperature, environment expected values at different times are formulated on line, trend analysis is carried out, and the automatic linkage air conditioner ventilation system keeps the set temperature, so that energy conservation and consumption reduction are realized.

Preferably, for the collected data from the dynamic monitoring module for greening and high-altitude monitoring, the central processing unit detects the acceleration of the moving object in the monitored data in real time, and distinguishes the condition of trampling the greening and the high-altitude falling object, and the appearance detection of the moving object is carried out in the image where the greening is located at the same time, so that the appearance detection is compared with the humanoid one.

Preferably, the dynamic monitoring module comprises a support column 1, a mounting seat 2 is fixedly mounted at the top of the support column 1, mounting plates 3 are mounted at two ends of the top of the mounting seat 2, a camera 4 is arranged at the top of the mounting plates 3, an adjusting mechanism 5 is mounted between the camera 4 and the top of the mounting plates 3, and a cruising mechanism 8 is mounted between the bottom of the mounting plates 3 and the mounting seat 2.

The management method based on the intelligent park provided by the application comprises the following steps:

step S1: setting and adjusting dynamic monitoring modules on the roadsides of the intelligent park, the edges of the greening zone and the ground outside the building wall surface, installing static monitoring modules on various electric facilities and auxiliary equipment, detecting environmental parameters in the intelligent park in real time through the dynamic monitoring modules, detecting operation parameters of the electric facilities and the auxiliary equipment in the intelligent park through the static monitoring modules, and uploading the acquired parameters to a central processor through communication equipment;

step S2: the central processing unit is used for carrying out classified integration processing on the acquired data, comparing the processed data with preset parameters of the intelligent park, and transmitting a processing result to the management platform;

step S3: the management platform is enabled to display the intelligent park preset parameter simulation model, the processed parameters are displayed at the corresponding positions of the model, the comparison difference data exceeds a preset threshold value, then the intelligent park preset parameter simulation model is displayed on the model, an alarm is sent out, and the intelligent park equipment is timely controlled through the execution module.

Preferably, a smart park based management device according to any of claims 1 to 6.

Preferably, the two cameras are adopted to cruise back and forth in a fan-shaped crossing mode, and the two cameras are patrolled and examined back and forth at a synchronous angle, or the angles of the two cameras are adjusted separately, so that the total monitoring height of the two cameras covers the whole building.

Compared with the prior art, the application has the following beneficial effects:

1. the intelligent monitoring system can monitor and manage the state of the park, automatically compare the design with the real-time parameter difference, give an alarm after the difference value is larger than the preset threshold value, facilitate timely finding and checking the problem, carry out timing treatment and improve the intelligent management degree of the park.

2. The application collects and monitors the parameters of the external environment of each road, greening and building in the park through the dynamic monitoring module, mainly collects moving objects appearing on greening and high-altitude falling objects outside the building, and the static monitoring module mainly detects auxiliary equipment such as electric facilities, water supply and the like in the park.

3. According to the method, after a simulation model is established according to the design data of the park, each monitoring data is processed and then is matched with the model, so that the problems that greening is damaged, high-altitude parabolic and other severe problems are frequently encountered in daily management of the park at present, and the problems are difficult to discover and trace in time after the problems occur are solved.

4. The application establishes a complete model for the park, establishes complete comprehensive security, space management and energy efficiency management, combines intelligent equipment, and enables the park energy efficiency to be controllable, visual and controllable by an informatization means.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of the structure of the present application.

Fig. 2 is a schematic diagram of the collecting device of the present application.

FIG. 3 is a schematic diagram of a management platform according to the present application.

Fig. 4 is a schematic structural diagram of a dynamic monitoring module according to the present application.

FIG. 5 is a schematic view of the structure of the adjusting mechanism of the present application.

FIG. 6 is a schematic view showing a cross-sectional structure of the cruise mechanism according to the present application.

Fig. 7 is a schematic view of the present application for monitoring a short building in a campus.

Figure 8 is a schematic view of the present application monitoring a campus high building.

Fig. 9 is a schematic structural diagram of an operation management module according to the present application.

FIG. 10 is a schematic diagram of the comprehensive security system of the present application.

FIG. 11 is a schematic diagram of the space management of the present application.

FIG. 12 is a schematic diagram of energy efficiency management according to the present application.

The figure shows:

Detailed Description

The present application will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the present application, but are not intended to limit the application in any way. It should be noted that variations and modifications could be made by those skilled in the art without departing from the inventive concept. These are all within the scope of the present application.

In order to solve the problem that the current park often encounters severe problems such as greening damage, high-altitude parabolic damage and the like in daily management, and the problems are difficult to discover and trace the source in time, the application aims to provide a management method and equipment based on an intelligent park.

As shown in fig. 1 to 12, the present application provides a smart park-based management apparatus, comprising:

the collection equipment is used for collecting environmental parameters in a park and running state parameters of various equipment;

the communication equipment is used for transmitting the data parameters acquired by the acquisition equipment to the central processing unit in real time;

the central processing unit coordinates each device to work, and is used for calling corresponding data in each database in the authority of the data calling command, sending the control commands to the corresponding devices, and analyzing and processing the acquired data through the central processing unit;

the management platform is used for displaying the data processed by each acquisition device in the park, so that the management is convenient;

and the storage device is used for storing the device running log and the parameters and providing data storage support.

Further, the collection equipment comprises a dynamic monitoring module and a static monitoring module, wherein the dynamic monitoring module is used for collecting and monitoring parameters of various roads, greening and building external environments in the park, and the static monitoring module is used for monitoring parameters of electric facilities in the park through various data sensors.

Through above-mentioned technical scheme, dynamic monitoring module is used for gathering the monitoring to each road in the garden, afforestation and building external environment parameter, mainly gather the motion thing that appears on the afforestation, and building outside high altitude junk gathers, static monitoring module detects auxiliary equipment such as electric power facility in the garden and water supply, if detect the equipment running state such as illumination in the garden, fire control, ventilation and heating through electric current, voltage sensor, state such as water flow sensor, water pressure sensor monitoring life water supply and prescribed time's afforestation irrigation, thereby in time discover garden equipment problem, reach the purpose of monitoring, be convenient for manage and discover earlier, early administer various problems.

Further, when the dynamic monitoring module monitors greening and high altitude, the central processing unit detects the acceleration of a moving object in the monitoring data in real time, and the conditions of trampling the greening and high altitude falling objects are distinguished, and the appearance of the moving object is detected and compared with the appearance of a person in the greening.

Further, the management platform includes:

the model module is used for carrying out simulation modeling according to the park design data and displaying the processed acquired data at the corresponding position of the model;

the display equipment is used for displaying parameters and models;

the alarm module is used for giving an alarm after the processed data is compared with the modeling standard data and is abnormal;

and the execution module is used for starting and stopping various electric facilities and accessory equipment in the park.

Through the technical scheme of the preferred embodiment, after the simulation model is established according to the park design data, each monitoring data is processed and then is positioned and matched with the model, so that the state of the park can be comprehensively monitored and managed, and an alarm is sent out after the difference value is larger than a preset threshold value through automatic comparison design and real-time parameter difference, so that problems can be found and checked in time, timing management is carried out, and the intelligent management degree of the park is improved.

Further, the dynamic monitoring module comprises a support column 1, an installation seat 2 is fixedly installed at the top of the support column 1, installation plates 3 are installed at two ends of the top of the installation seat 2, a camera 4 is arranged at the top of the installation plate 3, an adjusting mechanism 5 is installed between the camera 4 and the top of the installation plate 3, and a cruising mechanism 8 is installed between the bottom of the installation plate 3 and the installation seat 2.

As shown in fig. 4, further, the support column 1 comprises a fixed cylinder 11, the top of the inner cavity of the fixed cylinder 11 is slidably clamped with a supporting rod 12, the outer walls around the supporting rod 12 are all provided with pin holes, the top of the fixed cylinder 11 is slidably clamped with a locking bolt, the locking bolt is in threaded connection with the pin holes, the outer walls around the fixed cylinder 11 are fixedly provided with a U-shaped seat, one end of a connecting screw 7 is rotated in the U-shaped seat through a pin shaft, the other end of the screw 7 is in threaded sleeve connection with a threaded cylinder 6, and the other end of the threaded cylinder 6 far away from the screw 7 is hinged with a base.

As shown in fig. 5, further, the adjustment mechanism 5 includes a fixing plate 51, two fixing plates 51 are fixedly installed at one end of the mounting plate 3, a rotating shaft 52 is fixedly installed on the outer wall of the camera 4, the rotating shaft 52 is rotatably sleeved with the fixing plates 51, an adjustment groove 53 is formed in the fixing plates 51, a fixing rod 54 is fixedly installed on the outer wall of the camera 4, the fixing rod 54 penetrates through the adjustment groove 53, an insert 55 is slidably sleeved on the fixing rod 54, matched stop teeth 58 are arranged between the outer walls of two sides of the insert 55 and the inner walls of two sides of the adjustment groove 53, a stud 56 is fixedly installed on the end face of one end, far away from the camera 4, of the fixing rod 54, the stud 56 penetrates through the insert 55 and is in threaded sleeve joint with a locking nut 57, the locking nut 57 is tightly attached to the outer wall of the insert 55, the insert 55 and the adjustment groove 53 are in arc structures, the axes of the insert 55 and the adjustment groove 53 are overlapped with the axis of the rotating shaft 52, the cross section of the fixing rod 54 and the inner cavity of the insert 55 is in rectangular structure, and the size of the fixing rod 54 is equal to the thickness of the insert 55.

Through the technical scheme of the preferred embodiment, the fixing barrel 11 is fixed at the installation position through the foundation bolt, the supporting rod 12 slides along the fixing barrel 11 to adjust the height, then the locking bolt is locked and fixed, the threaded barrel 6 moves along the screw 7 to adjust the length, the base is attached to the ground and fixed through the foundation bolt, then the locking nut 57 is unscrewed, the inserting block 55 is pulled out of the adjusting groove 53, at the moment, the camera 4 can rotate through the rotating shaft 52 to adjust the pitch angle, the camera 4 can pick up the camera to the included angle to contain the monitoring range, then the inserting block 55 is inserted into the adjusting groove 53, the stop tooth 58 is meshed, the locking nut 57 is screwed with the stud 56 again, the fixing of the camera 4 is realized, and the quick installation setting is realized.

As shown in fig. 6, further, the cruising mechanism 8 includes a vertical shaft 81, the bottom of the mounting plate 3 is fixedly provided with the vertical shaft 81, the vertical shaft 81 is rotationally clamped in the mounting seat 2, a chute 82 is arranged in the mounting seat 2, a sliding plate 83 is slidably clamped in the chute 82, two sides of the sliding plate 83 are fixedly provided with a second rack 88, two driven gears 89 are fixedly sleeved on the two vertical shafts 81, the two driven gears 89 are respectively meshed with the two second racks 88, the middle part of the sliding plate 83 is provided with a connecting cavity 85, two side inner walls of the connecting cavity 85 are fixedly provided with a first rack 87, a motor 84 is fixedly arranged in the mounting seat 2 at the bottom of the chute 82, an output shaft of the motor 84 extends into the connecting cavity 85 and is fixedly sleeved with a half gear 86, and the half gear 86 is meshed with the first rack 87.

Through the technical scheme of the preferred embodiment, after the camera 4 is adjusted, the environment of the park is monitored in real time, data is uploaded, the motor 84 drives the half gear 86 to rotate, the half gear 86 is alternately meshed with the two first racks 87, reciprocating sliding of the sliding plate 83 is achieved, when the sliding plate 83 moves, the two second racks 88 drive the two driven gears 89 to reversely rotate, then the two second racks 88 drive the mounting plate 3 to reversely swing back and forth through the vertical shaft 81, and the two cameras 4 are in fan-shaped cross back and forth cruising, so that the monitoring range is improved.

As shown in fig. 9 to 12, the smart park-based management apparatus provided by the present application further includes:

and the operation management module is used for carrying out display management on buildings, security and energy efficiency in the park.

The operation management module comprises a comprehensive security module, a space management module and an energy efficiency management module.

The intelligent monitoring system is characterized in that the comprehensive security module monitors the park in real time, an event center, personnel defense, vehicle defense, fire-fighting linkage, video patrol and perimeter protection, monitors the park through a plurality of dynamic detection modules and static detection modules respectively by dynamic detection means and static detection means, establishes an electronic fence at the peripheral boundary of the intelligent park, detects invasion in an intelligent mode, carries out AI video intelligent analysis support through an intelligent video analysis system, actively discovers abnormal behaviors through video analysis, and issues a task work order according to the operation input of a commander when the alarm is true, wherein the task work order guides security personnel to navigate in place, predicts dangerous situations through videos and pictures and cooperatively processes, establishes personnel and vehicle defense according to the easy occurrence points of the forward accidents, facilitates quick response, adopts various fire-fighting sensing monitoring, and multi-system linkage fire-fighting mechanism, eliminates the post-safety environment to monitor, and collects various numerical value surrounding environment quality of the park. In addition, in more preferred embodiments of the application, the comprehensive security module combines weather forecast of a local area to publish the air pollution index and the dressing travel guide to park personnel in real time, establishes a BIM visual supervision platform for real-time monitoring, and links video monitoring for abnormal conditions, and displays a large screen bullet frame of a monitoring center;

the space management module performs park display, room information, recruitment information, meeting room information and cost analysis, is convenient for park recruitment display by establishing a complete park building model and room information, and realizes high-efficiency management by sharing service information in real time, and the management cost is analyzed by combining management and the recruitment information;

the energy efficiency management module is used for carrying out water and electricity monitoring, air conditioning monitoring, illumination monitoring, trend analysis and energy efficiency diagnosis, carrying out real-time monitoring on water and electricity, air conditioning and illumination of a park, monitoring the outdoor environment of the park, collecting various numerical values to evaluate the quality of the surrounding environment of the park, additionally installing environment sensors in important public areas such as underground parking lots, equipment rooms, canteens, laboratories and the like, carrying out real-time monitoring on the environment temperature, carrying out real-time alarm under the condition of abnormal temperature, making environment expected values at different times on line, carrying out trend analysis, and keeping the set temperature by the platform automatic linkage air conditioning ventilation system so as to achieve the purposes of energy conservation and consumption reduction.

The management method based on the intelligent park provided by the application comprises the following steps:

step S1, setting and adjusting dynamic monitoring modules on the sides of a park road, the edges of a greening area and the ground outside a building wall surface, installing static monitoring modules on various electric facilities and auxiliary equipment, detecting environment parameters in the park in real time through the dynamic monitoring modules, detecting operation parameters of the electric facilities and the auxiliary equipment in the park through the static monitoring modules, and uploading the acquired parameters to a central processor through communication equipment;

s2, the central processing unit performs classified integration processing on the acquired data, compares the processed data with preset parameters of a park, and transmits a processing result to the management platform;

and S3, the management platform displays the park preset parameter simulation model, displays the processed parameters at the corresponding positions of the model, remarkably displays and gives an alarm on the model after the comparison difference data exceeds a preset threshold value, and timely controls park equipment through the execution module, so that management personnel can manage the park equipment conveniently.

Further, the dynamic monitoring module setting and adjusting method comprises the following steps:

step S11, fixing a fixed cylinder 11 at an installation position through foundation bolts, sliding a supporting rod 12 along the fixed cylinder 11 to adjust the height, locking and fixing a locking bolt, moving a threaded cylinder 6 along a screw 7 to adjust the length by threads, enabling a base to be attached to the ground and fixed through the foundation bolts, unscrewing a locking nut 57, pulling an adjusting groove 53 out of an inserting block 55, rotating a pitching angle of a camera 4 through a rotating shaft 52 at the moment, enabling the shooting direction of the camera 4 to contain a monitoring range, inserting the inserting block 55 into the adjusting groove 53, meshing a stop tooth 58, screwing a locking nut 57 with a stud 56, and realizing the fixation of the camera 4 and quick installation setting;

step S12, the camera 4 monitors the environment of the park in real time after adjusting, data are uploaded, the motor 84 drives the half gear 86 to rotate, the half gear 86 is alternately meshed with the two first racks 87, the reciprocating sliding of the sliding plate 83 is achieved, when the sliding plate 83 moves, the two second racks 88 drive the two driven gears 89 to reversely rotate, then the two second racks 88 drive the mounting plate 3 to reversely swing back and forth through the vertical shaft 81, and the two cameras 4 are in fan-shaped cross back and forth cruising, so that the monitoring range is improved.

Further, the pitch angle of the cameras 4 can be adjusted to be consistent or different states so as to monitor the falling objects at the high altitude outside the building, as shown in fig. 7, aiming at the conditions of large external space and short building, the cameras 4 can be arranged at a far distance of the building, so that the whole height of the building can be directly collected after the pitch angle is adjusted by the cameras 4, and at the moment, the two cameras 4 can synchronously carry out round-trip inspection at an angle; as shown in fig. 8, when the external space is small and the building is high, at this time, one camera cannot fully collect the whole height of the building, so that the angles of the two cameras 4 are separately adjusted, the total monitoring height of the two cameras 4 covers the whole building, and the two cameras 4 patrol back and forth to achieve the purpose of comprehensive monitoring.

Working principle: fixing a fixed cylinder 11 at an installation position through an anchor bolt, sliding a supporting rod 12 along the fixed cylinder 11 to adjust the height, locking the locking bolt to be locked, moving a threaded cylinder 6 along a screw rod 7 to adjust the length by screwing, enabling a base to be attached to the ground and fixed through the anchor bolt, unscrewing a locking nut 57, pulling out an adjusting groove 53 by an inserting block 55, enabling a camera 4 to rotate through a rotating shaft 52 to adjust a pitch angle, enabling an included angle of shooting of the camera 4 to comprise a monitoring range, inserting the inserting block 55 into the adjusting groove 53, locking the locking tooth 58 to be meshed, screwing the locking nut 57 with a stud 56, achieving fixing of the camera 4, rapidly installing and setting, monitoring the environment of a park in real time after the camera 4 is adjusted, uploading data, driving a half gear 86 to rotate through a motor 84, enabling the half gear 86 to be meshed with two first racks 87 alternately, achieving reciprocating sliding of a sliding plate 83, and when the sliding plate 83 moves, the two second racks 88 drive the two driven gears 89 to reversely rotate, the two second racks 88 drive the mounting plate 3 to reversely swing back and forth through the vertical shaft 81, the two cameras 4 are in fan-shaped cross and back and forth cruising, the monitoring range is improved, the greening and high-altitude monitoring are realized, the acceleration of moving objects in the monitoring data is detected in real time through the central processing unit, the conditions of trampling the greening and high-altitude falling objects are distinguished, the appearance detection of moving objects is carried out in the greening, the appearance comparison is carried out, the situation of damaging the greening and high-altitude throwing objects in the park is determined, meanwhile, the static monitoring module mainly detects the electric facilities in the park and auxiliary equipment such as water supply and the like, for example, the running states of equipment such as illumination, fire protection, ventilation, heating and the like in the park are detected through the current and voltage sensors, the water flow sensors, the water pressure sensors and the like monitor the states such as living water supply and greening irrigation and the like for a set time, according to garden design data, after establishing simulation model, will fix a position after each monitoring data processing and the model match to can monitor management garden state comprehensively, and through automatic contrast design and real-time parameter difference, send out the alarm after the difference numerical value is greater than the threshold value of predetermineeing, be convenient for in time discover and check the department problem, control of timing improves garden wisdom management degree.

Those skilled in the art will appreciate that the systems, apparatus, and their respective modules provided herein may be implemented entirely by logic programming of method steps such that the systems, apparatus, and their respective modules are implemented as logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers, etc., in addition to the systems, apparatus, and their respective modules being implemented as pure computer readable program code. Therefore, the system, the apparatus, and the respective modules thereof provided by the present application may be regarded as one hardware component, and the modules included therein for implementing various programs may also be regarded as structures within the hardware component; modules for implementing various functions may also be regarded as being either software programs for implementing the methods or structures within hardware components.

The foregoing describes specific embodiments of the present application. It is to be understood that the application is not limited to the particular embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without affecting the spirit of the application. The embodiments of the application and the features of the embodiments may be combined with each other arbitrarily without conflict.

Claims (10)

1. A smart park-based management device, comprising:

acquisition equipment: collecting environmental parameters in an intelligent park and running state parameters of equipment in the park; the acquisition equipment comprises a dynamic monitoring module and a static monitoring module, wherein the dynamic monitoring module is used for acquiring and monitoring parameters of the external environment of each road, greening and building in the intelligent park, and the static monitoring module is used for monitoring parameters of electric facilities of the intelligent park through each data sensor;

and the central processing unit: calling corresponding data as a control command according to the data calling command, sending the control command to corresponding in-park equipment, and analyzing and processing the acquired data acquired from the in-park equipment;

and (3) a management platform: and displaying the data analyzed and processed by the central processing unit.

2. The smart campus-based management device of claim 1, wherein the management platform comprises:

model module: simulation modeling is carried out according to the design data of the intelligent park to obtain a model, and the acquired data processed by the central processing unit is displayed at the corresponding position of the model;

display device: displaying parameters and models;

an alarm module: comparing the data processed by the central processing unit with modeling standard data, and sending out an alarm after the comparison result indicates that the abnormality occurs;

the execution module: various electric facilities and auxiliary equipment in the intelligent park are started and stopped according to the alarm.

3. The smart campus-based management device of claim 1, further comprising:

operation management module: and carrying out display management on the building, security and energy efficiency in the intelligent park.

4. The smart campus-based management device of claim 3, wherein the operations management module comprises:

and the comprehensive security module is used for: and setting up an electronic fence at the peripheral boundary of the intelligent park, calling a dynamic detection module and a static detection module to detect the target behavior of the invasive electronic fence, and issuing a task work order according to the operation input of a commander, wherein the task work order guides security personnel to navigate in place.

5. The smart campus-based management device of claim 4, wherein the operations management module comprises:

and a space management module: establishing a complete intelligent park building model and room information, displaying intelligent park quotations, and sharing service information in real time;

and the energy efficiency management module is used for: the water power monitoring, air conditioning monitoring, illumination monitoring, trend analysis and energy efficiency diagnosis are carried out, the water power, air conditioning and illumination of the intelligent park are monitored in real time, the outdoor environment of the intelligent park is monitored, the quality of the environment around the intelligent park is assessed by collecting various values, the environment temperature is monitored in real time, the alarm is given in real time under the condition of abnormal temperature, environment expected values at different times are formulated on line, trend analysis is carried out, and the automatic linkage air conditioner ventilation system keeps the set temperature, so that energy conservation and consumption reduction are realized.

6. The intelligent park-based management device according to claim 1, wherein for collected data from the dynamic monitoring module for greening and high-altitude monitoring, the central processor detects the acceleration of the moving object in the monitored data in real time, and distinguishes the condition of trampling greening and high-altitude falling objects, and the appearance detection of the moving object is performed simultaneously in the image where greening is located, and is compared with the appearance of a person.

7. The intelligent park-based management device according to claim 1, wherein the dynamic monitoring module comprises a support column (1), an installation seat (2) is fixedly installed at the top of the support column (1), installation plates (3) are installed at two ends of the top of the installation seat (2), a camera (4) is arranged at the top of the installation plate (3), an adjusting mechanism (5) is installed between the camera (4) and the top of the installation plate (3), and a cruising mechanism (8) is installed between the bottom of the installation plate (3) and the installation seat (2).

8. A smart park-based management method, comprising:

step S1: setting and adjusting dynamic monitoring modules on the roadsides of the intelligent park, the edges of the greening zone and the ground outside the building wall surface, installing static monitoring modules on various electric facilities and auxiliary equipment, detecting environmental parameters in the intelligent park in real time through the dynamic monitoring modules, detecting operation parameters of the electric facilities and the auxiliary equipment in the intelligent park through the static monitoring modules, and uploading the acquired parameters to a central processor through communication equipment;

step S2: the central processing unit is used for carrying out classified integration processing on the acquired data, comparing the processed data with preset parameters of the intelligent park, and transmitting a processing result to the management platform;

step S3: the management platform is enabled to display the intelligent park preset parameter simulation model, the processed parameters are displayed at the corresponding positions of the model, the comparison difference data exceeds a preset threshold value, then the intelligent park preset parameter simulation model is displayed on the model, an alarm is sent out, and the intelligent park equipment is timely controlled through the execution module.

9. The smart campus-based management method of claim 8, wherein the smart campus-based management apparatus of any one of claims 1 to 6 is based.

10. The intelligent park-based management method according to claim 8, wherein two cameras are adopted to cruise back and forth in a fan-shaped cross and to patrol back and forth at a synchronous angle, or the angles of the two cameras are adjusted separately so that the total monitoring height of the two cameras covers the whole building.