CN115527356A - New energy open-air infrastructure construction site environment monitoring system and method - Google Patents

Abstract

The invention provides a new energy open-air infrastructure field environment monitoring system and a new energy open-air infrastructure field environment monitoring method, wherein an unmanned aerial vehicle technology is applied to a construction process, image information, temperature information and noise information are collected, the information collection capability of the new energy infrastructure construction process in the open-air environment is improved, and long-term field data collection can be carried out on a construction site. The system collects relevant environmental information, carries out comparison judgment and simulation prediction on the collected environmental information, alarms when the temperature or noise exceeds a threshold value, carries out simulation prediction on the environmental change of a construction site when the temperature or noise does not exceed the threshold value, assists workers to find out the local environmental change and potential safety risk caused by construction in time, provides basis for the constructors to adjust the construction flow, enhances the timeliness of supervision on the construction process, improves the efficiency of the construction process, reduces the influence on the local environment in the engineering construction process and eliminates the irreversible damage to the local environment in time.

Description

New energy open-air infrastructure site environment monitoring system and method

Technical Field

The invention relates to new energy intelligent infrastructure, in particular to a new energy open-air infrastructure field environment monitoring system and a new energy open-air infrastructure field environment monitoring method.

Background

The new energy mainly refers to energy represented by solar energy, wind energy and the like, and compared with the traditional fossil energy, the new energy has the following characteristics: strong reproducibility, no environmental pollution and rich resources, and can be used by human for a long time. However, the construction and construction of new energy infrastructure projects mostly involve the transformation of large-scale environments, so that the environment is damaged and polluted to a certain extent in the development process of new energy, the pollutants are diffused along with the air flow, the environment in a larger range is damaged, the environmental protection problem in the construction process of new energy infrastructures is concerned more and more, the monitoring on the environment change is enhanced, the damage to local environments is reduced, and the method becomes one of important directions for the development of new energy infrastructures gradually.

However, the traditional construction process is difficult to control the change of various conditions and factors in the process, and especially in a large-scale open environment, the problems of large workload, multiple blind spots, localized information acquisition, lag and the like exist by only depending on a manual inspection mode, so that the real-time, overall, omnibearing and uninterrupted control of a construction site is difficult to realize. In addition, the existing inspection mode is difficult to provide timely and complete feedback information for engineering construction adjustment.

Disclosure of Invention

Aiming at the influence on local environment in the new energy open-air infrastructure construction process, the invention provides a new energy open-air infrastructure construction site environment monitoring system and method, which can timely and comprehensively acquire environment change information in the new energy infrastructure construction process in the open-air environment, and can timely adjust a construction scheme according to the environment change information, thereby reducing the pollution and irreversible damage to the environment.

The invention is realized by the following technical scheme:

a new energy open-air capital construction field environment monitoring system comprises an unmanned aerial vehicle, a computer processing module and an alarm module; the unmanned aerial vehicle is provided with an information acquisition module;

the unmanned aerial vehicle is used for cruising at a new energy open-air infrastructure site, acquiring image information, temperature information and noise information of a construction site environment through the information acquisition module, and transmitting the image information, the temperature information and the noise information to the computer processing module;

the computer processing module is used for comparing the received noise information with a noise threshold value, comparing the received temperature information with a temperature threshold value, if the noise information is higher than the noise threshold value or the temperature information is higher than the temperature threshold value, starting the alarm module, otherwise, extracting the position information of the sound generating equipment and the position information of the heating equipment from the image information, and carrying out numerical simulation prediction on the atmospheric change trend of the construction site environment by combining the noise information and the temperature information to obtain and output a simulation prediction result;

and the alarm module is used for giving an alarm when the noise is higher than the noise threshold value or the temperature is higher than the temperature threshold value.

Preferably, the information collecting module includes: the device comprises a camera, a temperature sensor and a noise sensor;

the camera is used for collecting image information of the construction site environment and transmitting the image information to the computer processing module; the temperature sensor is used for acquiring temperature information of the construction site environment and transmitting the temperature information to the computer processing module; the noise sensor is used for collecting noise information of the construction site environment and transmitting the noise information to the computer processing module.

Furthermore, the information acquisition module also comprises a dust acquisition device for acquiring dust samples of the construction site environment;

and the alarm module is also used for alarming when the pollutants in the dust sample exceed the standard.

Further, set up many unmanned aerial vehicles, every unmanned aerial vehicle gathers one of image information, temperature information, noise information and dust sample.

Furthermore, the unmanned aerial vehicle for collecting dust samples is provided with a single chip microcomputer and a mass sensor; quality sensor gathers dust collection system's quality information and transmits for the singlechip, and the singlechip judges whether dust collection system fills with according to the quality information who receives, if fill with, then control unmanned aerial vehicle and return and set for the position.

A new energy open-air capital construction site environment monitoring method comprises the following steps: the method comprises the following steps that an unmanned aerial vehicle is adopted to cruise a new energy open-air infrastructure site, and image information, noise information and temperature information of a construction site environment are collected;

and comparing the noise information with a noise threshold, comparing the temperature information with a temperature threshold, alarming if the noise information is higher than the noise threshold or the temperature information is higher than the temperature threshold, otherwise, extracting the position information of the sound generating equipment and the position information of the heating equipment from the image information, and carrying out numerical simulation prediction on the atmospheric change trend of the construction site environment by combining the noise information and the temperature information to obtain and output a simulation prediction result.

Further, the numerical simulation prediction of the atmospheric variation trend of the construction site environment specifically includes:

(1) Constructing a three-dimensional space model of a construction site through image information and carrying out grid division;

(2) Setting boundary conditions and related physical property calculation parameters of sound field calculation in a three-dimensional space model;

(3) Calculating the steady-state sound field distribution by adopting an absorption attenuation model to obtain pressure distribution;

(4) Setting initial conditions, boundary conditions and related physical property calculation parameters of fluid flow and heat transfer in a three-dimensional space model;

(5) And (4) taking the pressure distribution obtained in the step (3) as the volume force calculated by the flow field, enabling the heating equipment to be equivalent to a heat source at a known space geometric position, and coupling the flow field and the temperature field to perform numerical calculation simulation to obtain a simulation prediction result.

Further, in the step (3), when the steady-state sound field distribution is calculated, the adopted control equation is a pressure acoustic equation under a frequency domain; in the step (5), when the flow field and the temperature field are coupled to carry out numerical calculation simulation, the flow field control equation is a continuous equation, an N-S equation for adding a volume force term and an energy equation for adding a heat source term, and the heat transfer equation is a transient fluid heat transfer equation.

Preferably, the extracting of the sound generating device position information and the heat generating device position information from the image information specifically includes: the image information is denoised by adopting a corrosion algorithm, then a target image is extracted from the denoised image information by adopting a binarization algorithm, finally the target image is strengthened by adopting an image strengthening algorithm, and geometric topological analysis is carried out on the images at different moments according to the strengthened target image so as to determine the position of a noise source and the position of high-calorific-value equipment.

Preferably, the method further comprises the following steps: the method comprises the steps that an unmanned aerial vehicle is adopted to cruise on a new energy open-air infrastructure site, dust samples of a construction site environment are collected, after the dust samples are collected, the unmanned aerial vehicle flies back to a set position, and component inspection is carried out on the collected dust samples to obtain an inspection result; if the inspection result shows that the pollutants in the dust sample exceed the standard, an alarm is given to remind workers to stop construction; and if the pollutants in the dust sample do not exceed the standard, storing the detection result.

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

according to the system, aiming at the influence on the environment in the new energy open-air infrastructure construction process, the unmanned aerial vehicle technology is applied to the construction process, image information, temperature information and noise information are collected, the information collection capability of the new energy infrastructure construction process in the open-air environment is improved, and long-term field data collection can be carried out on a construction site. The system collects relevant environmental information, carries out comparison judgment and simulation prediction on the collected environmental information, alarms when the temperature or noise exceeds a threshold value, carries out simulation prediction on the environmental change of a construction site when the temperature or noise does not exceed the threshold value, assists workers to find out the local environmental change and potential safety risk caused by construction in time, further provides a basis for the constructors to adjust the construction flow, enhances the timeliness of supervision on the construction process, improves the efficiency of the construction process, reduces the influence on the local environment in the engineering construction process and eliminates the irreversible damage to the local environment in time.

Furthermore, the invention also collects dust samples, monitors whether the pollution in the environment exceeds the standard or not by detecting the dust samples, and timely informs field personnel to take active measures if the pollution in the environment exceeds the standard, thereby timely correcting the environment pollution condition.

Furthermore, each unmanned aerial vehicle is only responsible for collecting one environmental information of image information, temperature information, noise information and dust information; thereby reduce single unmanned aerial vehicle's transformation cost, to the influence of other environmental information collection when avoiding single unmanned aerial vehicle to break down, the at utmost guarantees to gather environmental information's integrality and accuracy, has reduced the complexity of programming.

Drawings

Fig. 1 is a block diagram of a new energy open-air infrastructure field environment monitoring system.

Fig. 2 is a flowchart of a new energy open-air infrastructure field environment monitoring method.

FIG. 3 is a flow chart of numerical simulation prediction calculation according to the present invention.

Detailed Description

For a further understanding of the invention, reference will now be made to the following examples, which are provided to illustrate further features and advantages of the invention, and are not intended to limit the scope of the invention as set forth in the following claims.

As shown in fig. 1, the new energy open-air infrastructure field environment monitoring system of the invention comprises an unmanned aerial vehicle, a computer processing module and an alarm module; the unmanned aerial vehicle is provided with an information acquisition module; the computer processing module comprises an information processing module and an information output module.

The unmanned aerial vehicle is used for cruising at a new energy open-air infrastructure site, and acquiring local environment information through the information acquisition module, wherein the local environment information comprises image information, temperature information, noise information and dust samples; specifically, image information, temperature information and noise information of the construction site environment are collected through the information collection module and transmitted to the information processing module, dust samples in air of the local construction site are collected through the information collection module, and dust components are subsequently detected manually.

The information processing module compares the received noise information with a noise threshold value, compares the received temperature information with a temperature threshold value, and starts the alarm module to inform workers of site construction if the noise is higher than the noise threshold value or the temperature is higher than the temperature threshold value; otherwise, processing the received image information, extracting the position of the sound generating equipment and the position of the heating equipment from the image information, generating a three-dimensional space model of the construction site, and carrying out numerical simulation prediction on the atmospheric variation trend of the construction site by combining the collected noise information and the temperature information by using a numerical calculation method to obtain a simulation prediction result.

And the information output module is used for outputting the simulation prediction result obtained by the information processing module.

And the alarm module is used for giving an alarm when the noise is higher than the noise threshold value or the temperature is higher than the temperature threshold value and giving an alarm when pollutants in the dust sample exceed the standard.

Wherein, the camera should have high definition; a resolution of not less than 4k is used. The temperature sensor has the measurement precision requirement that the change of the temperature fluctuation exceeding 0.5 ℃ can be quickly detected; noise sensors require precision to quickly detect changes in noise fluctuations beyond 7 dB.

A single unmanned aerial vehicle is only responsible for gathering an environmental information, can reduce unmanned aerial vehicle repacking cost like this, even certain unmanned aerial vehicle damages and does not influence the collection of other environmental information yet, and the most important can use the parallel programming framework, reduces the degree of difficulty of programming. The number of unmanned aerial vehicles used for each information acquisition is determined by the size of a construction site. Be responsible for gathering the unmanned aerial vehicle of dust sample and add the control circuit integrated module and the response dust collection system's that use the singlechip as the core quality sensor at the repacking in-process, deposit the judgement analysis program that detects dust collection system quality change in advance in the singlechip, set for collection system's quality or capacity information in the procedure for judge whether dust fills with, if fill with then return through program control unmanned aerial vehicle and set for the position.

As shown in fig. 2, the method for monitoring the environment of the new energy open-air infrastructure site of the invention comprises the following specific implementation processes:

firstly, adopt unmanned aerial vehicle to gather job site environment's image information, noise information, temperature information and gather the dust sample.

Then, the unmanned aerial vehicle transmits the acquired image information, the acquired noise information and the acquired temperature information back to the information processing module. The noise value and the temperature value are judged in the information processing module, if at least one index in the noise or the temperature exceeds the corresponding threshold value, the alarm module is directly started to remind workers to stop construction, and potential safety hazards in the construction environment are checked or the construction flow is adjusted; and if the noise and the temperature do not exceed the corresponding threshold values, processing image information, extracting the position information of the sound generating equipment and the position information of the heating equipment by adopting an image processing technology, generating a three-dimensional space model of the construction site, and carrying out numerical simulation prediction on the atmospheric change trend of the construction site by combining the collected noise information and the collected temperature information by using a numerical calculation method to obtain a simulation prediction result.

In a calculation mode of predicting the atmospheric change trend of a construction site by numerical simulation, the method does not adopt a common multi-physical-field coupling calculation mode of a sound field, a temperature field and a flow field, because the calculation mode has higher accuracy but longer calculation time, and cannot meet the requirement of coping with the constantly-changing environment of the construction site; therefore, in order to simulate and predict the change process of the environment quickly and accurately, the invention adopts the calculation flow shown in fig. 3 in the aspect of numerical simulation prediction:

(1) Constructing a three-dimensional space model of a construction site through image information and carrying out grid division;

(2) Setting boundary conditions and related physical property calculation parameters of sound field calculation in a three-dimensional space model;

(3) Calculating the steady sound field distribution by adopting an absorption attenuation model to obtain pressure distribution; the control equation in the process uses a pressure acoustic equation (namely in the form of Helmholtz equation) in a frequency domain;

(4) Setting initial conditions, boundary conditions and related physical property calculation parameters of fluid flow and heat transfer in a three-dimensional space model;

(5) Taking the pressure distribution obtained in the step (3) as a volume force calculated by a flow field, wherein the heating equipment is equivalent to a heat source at a known space geometric position in the calculation; performing numerical calculation simulation on the coupled flow field and the temperature field, wherein a flow field control equation adopts a continuous equation, an N-S equation (adding a volume force term) and an energy equation (adding a heat source term); the heat transfer equation adopts a transient fluid heat transfer equation;

(6) And (5) outputting a numerical calculation simulation result which is used as a basis for researching and analyzing the influence on the environment in the construction process and provides reference for optimizing the construction flow at the later stage.

To explain further: because the natural flow speed in the atmospheric environment is very slow, the capability of improving the heat transfer rate is far inferior to the condition that forced convection exists, and a local area with larger pressure gradient does not exist; therefore, the background flow field is approximately considered to be stable, the initial speed is zero, and the pressure is atmospheric pressure; and in addition, the numerical simulation prediction is carried out, namely, if the sound generating equipment and the heat generating equipment which exceed a preset threshold value do not exist in the construction environment, the flow driving force in the atmospheric flow field is approximately considered to be from the gravity and the sound disturbance of the sound generating equipment.

And finally, outputting the prediction result by an information output module to provide reference for workers, and adjusting the construction process and the progress by the workers according to the prediction result.

When the above-mentioned work flow goes on, unmanned aerial vehicle constantly gathers dust sample at the flight in-process. After the dust sample collecting device is filled, the unmanned aerial vehicle automatically sets a fly-back set position according to a program and takes the collected dust sample down by a worker for component inspection to obtain an inspection result; if the inspection result shows that the pollutants in the dust sample exceed the standard, the alarm module is directly started to remind workers of stopping construction; and if the pollutants in the dust sample do not exceed the standard, storing the detection result.

According to the construction method, the unmanned aerial vehicle is used for collecting real-time information of a construction site, the computer processing module is used for rapidly identifying local environment change and safety risk caused by construction, and feedback is made in time to help constructors to adjust schemes, so that potential damage caused by the local environment change is eliminated. The system can effectively enhance the information acquisition capacity of the new energy open-air infrastructure construction process, ensure the safety of constructors, timely adjust the construction flow, reduce the pollution to the local environment and eliminate the irreversible damage to the local environment.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Claims (10)

1. A new energy open-air infrastructure site environment monitoring system is characterized by comprising an unmanned aerial vehicle, a computer processing module and an alarm module; the unmanned aerial vehicle is provided with an information acquisition module;

the unmanned aerial vehicle is used for cruising at a new energy open-air infrastructure site, acquiring image information, temperature information and noise information of a construction site environment through the information acquisition module, and transmitting the image information, the temperature information and the noise information to the computer processing module;

the computer processing module is used for comparing the received noise information with a noise threshold value, comparing the received temperature information with a temperature threshold value, if the noise information is higher than the noise threshold value or the temperature information is higher than the temperature threshold value, starting the alarm module, otherwise, extracting the position information of the sound generating equipment and the position information of the heating equipment from the image information, and carrying out numerical simulation prediction on the atmospheric change trend of the construction site environment by combining the noise information and the temperature information to obtain and output a simulation prediction result;

and the alarm module is used for giving an alarm when the noise is higher than the noise threshold value or the temperature is higher than the temperature threshold value.

2. The system for monitoring the environment in the open-air infrastructure site of new energy according to claim 1, wherein the information acquisition module comprises: the device comprises a camera, a temperature sensor and a noise sensor;

the camera is used for collecting image information of the construction site environment and transmitting the image information to the computer processing module; the temperature sensor is used for acquiring temperature information of the construction site environment and transmitting the temperature information to the computer processing module; the noise sensor is used for collecting noise information of the construction site environment and transmitting the noise information to the computer processing module.

3. The new energy open-air infrastructure site environment monitoring system of claim 2, wherein the information collection module further comprises a dust collection device for collecting a dust sample of a job site environment;

and the alarm module is also used for alarming when the pollutants in the dust sample exceed the standard.

4. The system and method for monitoring the environment of the open-air infrastructure site of new energy according to claim 3, wherein a plurality of unmanned aerial vehicles are provided, and each unmanned aerial vehicle collects one of image information, temperature information, noise information and dust samples.

5. The new energy open-air infrastructure site environment monitoring system of claim 4, wherein the unmanned aerial vehicle collecting dust samples is equipped with a single chip microcomputer and a mass sensor; quality sensor gathers dust collection system's quality information and transmits for the singlechip, and the singlechip judges whether dust collection system fills according to the quality information who receives, if fill, then control unmanned aerial vehicle returns and sets for the position.

6. A new energy open-air capital construction site environment monitoring method is characterized by comprising the following steps: the method comprises the steps that an unmanned aerial vehicle is adopted to cruise on a new energy open-air infrastructure site, and image information, noise information and temperature information of a construction site environment are collected;

and comparing the noise information with a noise threshold, comparing the temperature information with a temperature threshold, if the noise information is higher than the noise threshold or the temperature information is higher than the temperature threshold, giving an alarm, otherwise, extracting the position information of the sound generating equipment and the position information of the heating equipment from the image information, and carrying out numerical simulation prediction on the atmospheric change trend of the construction site environment by combining the noise information and the temperature information to obtain and output a simulation prediction result.

7. The method for monitoring the environment of the new energy open-air infrastructure site according to claim 6, wherein the numerically simulated prediction of the atmospheric variation trend of the construction site environment specifically comprises:

(1) Constructing a three-dimensional space model of a construction site through image information and carrying out grid division;

(2) Setting boundary conditions and related physical property calculation parameters of sound field calculation in a three-dimensional space model;

(3) Calculating the steady-state sound field distribution by adopting an absorption attenuation model to obtain pressure distribution;

(4) Setting initial conditions, boundary conditions and related physical property calculation parameters of fluid flow and heat transfer in a three-dimensional space model;

(5) And (4) taking the pressure distribution obtained in the step (3) as the volume force calculated by the flow field, enabling the heating equipment to be equivalent to a heat source at a known space geometric position, and coupling the flow field and the temperature field to perform numerical calculation simulation to obtain a simulation prediction result.

8. The method for monitoring the environment in the open-air infrastructure site of the new energy according to claim 7, wherein in the step (3), the control equation adopted in the calculation of the steady-state sound field distribution is a pressure acoustic equation in a frequency domain; in the step (5), when the flow field and the temperature field are coupled to carry out numerical calculation simulation, the flow field control equation is a continuous equation, an N-S equation for adding a volume force term and an energy equation for adding a heat source term, and the heat transfer equation is a transient fluid heat transfer equation.

9. The method for monitoring the environment of the new energy open-air infrastructure site according to claim 6, wherein the extracting of the position information of the sound generating device and the position information of the heat generating device from the image information is specifically: denoising the image information by adopting a corrosion algorithm, extracting a target image from the denoised image information by adopting a binarization algorithm, strengthening the target image by adopting an image strengthening algorithm, and carrying out geometric topology analysis on the images at different moments according to the strengthened target image so as to determine the position of a noise source and the position of equipment with high calorific value.

10. The method for monitoring the environment of the open-air infrastructure site of new energy according to claim 6, further comprising: the method comprises the steps that an unmanned aerial vehicle is adopted to cruise on a new energy open-air infrastructure site, dust samples of a construction site environment are collected, after the dust samples are collected, the unmanned aerial vehicle flies back to a set position, and component inspection is carried out on the collected dust samples to obtain an inspection result; if the inspection result shows that the pollutants in the dust sample exceed the standard, alarming to remind workers to stop construction; and if the pollutants in the dust sample do not exceed the standard, storing the detection result.

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