CN115293666A - Quick building method for park safety risk control platform based on low-code platform - Google Patents

Abstract

The invention relates to the technical field of data processing systems, in particular to a method for quickly building a park safety risk control platform based on a low-code platform, which comprises the following steps: analyzing the property of the garden, acquiring the risk type of the garden, constructing a garden partition logic according to the risk type of the garden, and performing regional division on the garden by applying the garden partition logic; acquiring the specific risk items of each park subarea, and evaluating the park subarea risk level according to the specific risk items of the park subareas; acquiring park area division result data, and building a model of the multi-plate park by referring to the division result data; the invention can effectively perform regional division management on the garden, construct the garden model on the basis of the regional division so that a user side can perform overall management on the garden through the garden model, further capture garden roads in the garden model, and configure safety routes for all the subareas according to the safety risk degree of the garden subareas.

Description

Quick building method for park safety risk control platform based on low-code platform

Technical Field

The invention relates to the technical field of data processing systems, in particular to a method for quickly building a park safety risk control platform based on a low-code platform.

Background

Hazardous chemicals refer to highly toxic chemicals and other chemicals which have the properties of toxicity, corrosion, explosion, combustion supporting and the like and have harm to human bodies, facilities and environments, are mainly produced in industrial parks, bring certain positive growth to the life and economic development of people, but have the particularity of physical and chemical properties in the hesitation period, and have more safety threat factors in the production process.

At present, the safety management in chemical production garden, mainly through monitoring devices and the artifical mode of patrolling and examining and reading monitoring devices monitoring data comes to carry out the management and control of safety risk to the chemical production garden, this kind of mode has consumed a large amount of hand labors, and the manual work is patrolled and examined and is unable to be monitored completely, thereby the data authenticity that the manual work was patrolled and examined lacks, so that some hidden safety risks as for the chemical production garden can't in time discover, in addition because dangerization variety class is various, there is certain difference in production and storage process, consequently want to be a safety risk management and control platform configuration for appointed dangerization article design safety risk management and control platform lengthy and complicated, high design cost has also been caused simultaneously for dangerization article design safety risk management and control platform in one by one.

Disclosure of Invention

Solves the technical problem

Aiming at the defects in the prior art, the invention provides a method for quickly building a park safety risk management and control platform based on a low-code platform, and solves the technical problems in the background technology.

Technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme:

a method for quickly building a park safety risk management and control platform based on a low-code platform comprises the following steps:

step 1: analyzing the property of the garden, acquiring the risk type of the garden, constructing a garden partition logic according to the risk type of the garden, and performing regional division on the garden by applying the garden partition logic;

step 2: acquiring the specific risk items of each park subarea, and evaluating the park subarea risk level according to the specific risk items of the park subareas;

and step 3: acquiring park area division result data, and building a model of the multi-plate park by referring to the division result data;

and 4, step 4: capturing a park road model in the multi-plate park model, configuring the park road model with a subarea area in the multi-plate park model, and generating a safety path according to the park subarea risk level;

and 5: deploying monitoring equipment to each park partition, receiving data acquired by the monitoring equipment in real time, and synchronously configuring an acquisition cycle and a feedback cycle of the data acquired by the monitoring equipment;

and 6: setting a safety threshold value of data collected by monitoring equipment, and triggering and operating an audio alarm according to the set safety threshold value;

and 7: and calculating the risk value of the park according to the data acquired by the monitoring equipment and the set safety threshold value.

Furthermore, the property content and the risk type of the park in the step 1 are analyzed and acquired according to the product type of the park, the step 1 synchronously constructs a data repository during execution, and the content data obtained by the step 1 is stored each time the method application initializes the step 1.

Furthermore, the specific items of the campus partition risk acquired in step 2 are manually edited and set by a user or identified according to the campus product type and the product chain logic.

Further, the multi-plate park model constructed in step 3 includes a two-dimensional model and a three-dimensional model, wherein the two-dimensional model of the multi-plate park is used for being viewed by a user, and the three-dimensional model of the multi-plate park is applied to the following step 3, which is executed in a next sub-step, and includes the following steps:

step 31: and (3) acquiring the assessment result of the park subarea risk level in the step (2), and setting the threat space range corresponding to the park subarea risk level according to the multi-plate park model.

Furthermore, the safety paths generated in the step 4 are synchronously packaged and distributed to each mobile electronic device in the campus through a wireless network;

the safety path packaging file judges the position information of the mobile electronic equipment before distribution, and after the position information of the mobile electronic equipment is judged, the safety path corresponding to the park zone is selected according to the position information of the mobile electronic equipment to carry out setting coordination before the packaging file.

Further, the data content collected by the monitoring device in step 5 includes: environmental temperature and humidity data, environmental gas composition parameters, equipment working state parameters and current unfinished working hour data of park workers;

the acquisition period and the feedback period of the acquired data of the monitoring equipment are set according to user definition of a user side, and the acquisition period and the feedback period are initially set to be three seconds/time and fifteen minutes/time by default;

and the data acquisition times of the monitoring equipment checked by the user side in the time threshold range of every four groups of feedback cycles are more than or equal to 1.

Further, the step 4 and the step 5 are provided with sub-steps, including the following steps:

step 51: configuring a monitoring equipment signal generator, and configuring a computer to receive data acquired by real-time operation of monitoring equipment;

step 52: when the computer receives real-time operation acquisition data sent by monitoring equipment, acquiring position information of the monitoring equipment corresponding to the received acquisition data synchronously through a signal generator configured on the monitoring equipment;

step 53: and deploying audio alarms in each park zone, and performing priority triggering control on the audio alarms corresponding to the position information of the monitoring equipment according to the signal generator.

Furthermore, the number of the audio alarms deployed in the subareas of the park is more than or equal to 2, and each group of audio alarm connecting circuits is set to be parallel.

Furthermore, in the step 6, the audio alarm triggers logic synchronization to be sent to the data repository and stored according to the safety threshold set by the data collected by the monitoring equipment.

Furthermore, the campus risk value calculation in step 7 is provided with an operation cycle, and the operation cycle is synchronously and coordinately set according to the collected data feedback cycle of the monitoring device, where the formula is as follows:

；

in the formula, R is a risk superposition value showing a major hazard source in a chemical industrial park, (= 1,2, N);

the probability of accident occurrence of the 1 st major hazard source;

the 1 st major hazard source accident is the result caused by the 1 st major hazard source accident, namely the accident causes the death of personnel, and the probability value is used for representing;

FR is the fire emergency rescue coefficient;

MR is the treatment emergency rescue coefficient.

Advantageous effects

Compared with the known public technology, the technical scheme provided by the invention has the following beneficial effects:

1. the invention provides a method for quickly building a park safety risk control platform based on a low-code platform, which can effectively divide and manage the park by regions through the steps in the method, constructs a park model on the basis of the divided regions so that a user can conveniently carry out overall management on the park through the park model, further captures park roads in the park model, and configures safety routes for all the partitions according to the safety risk degree of the park partitions so as to ensure that park workers can quickly and orderly evacuate when dealing with dangerous conditions.

2. In the step execution process of the invention, the risk assessment can be carried out on the divided park partitions, so that the subsequent park workers can conveniently make priority selection on the safety management of the park, and the safety risk of the park is ensured to be adaptively treated.

3. In the process of executing the steps, the method can also configure reasonable monitoring equipment planning for the park, and can bring certain early warning effect to workers and managers in the park through periodic data acquisition and setting and comparing of safety threshold values of the data under the state of configuring the monitoring equipment, thereby avoiding the occurrence and expansion of safety risk accidents as much as possible.

Drawings

In order to more clearly illustrate the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 is a schematic flow diagram of a method for quickly building a park security risk management and control platform based on a low-code platform.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The present invention will be further described with reference to the following examples.

Example 1

The method for quickly building the park safety risk control platform based on the low-code platform in the embodiment is shown in fig. 1 and comprises the following steps:

step 1: analyzing the property of the garden, acquiring the risk type of the garden, constructing a garden partition logic according to the risk type of the garden, and performing regional division on the garden by applying the garden partition logic;

step 2: acquiring the specific risk items of each park subarea, and evaluating the park subarea risk level according to the specific risk items of the park subareas;

and step 3: acquiring park area division result data, and building a model of the multi-plate park by referring to the division result data;

and 4, step 4: capturing a park road model in the multi-plate park model, configuring the park road model with a subarea area in the multi-plate park model, and generating a safety path according to the park subarea risk level;

and 5: deploying monitoring equipment to each park partition, receiving data acquired by the monitoring equipment in real time, and synchronously configuring an acquisition cycle and a feedback cycle of the data acquired by the monitoring equipment;

and 6: setting a safety threshold value of data collected by monitoring equipment, and triggering and operating an audio alarm according to the set safety threshold value;

and 7: and calculating the risk value of the park according to the data collected by the monitoring equipment and the set safety threshold value.

Example 2

Preferably, the property content and the risk type of the park in the step 1 are analyzed and acquired according to the product type of the park, the step 1 is synchronously constructed during execution, and the content data obtained by the step 1 is stored every time the method application initialization step 1 is executed.

Through the setting, the content data executed in the step 1 can be stored, so that the method can be supported by a certain amount of data when being applied to other gardens subsequently, and the efficiency of the method and the garden configuration is improved.

Preferably, the specific items of the campus sector risk obtained in step 2 are manually edited and set by a user or identified according to the campus product type and the product chain logic.

Preferably, the multi-plate park model constructed in the step 3 includes a two-dimensional model and a three-dimensional model, wherein the two-dimensional model of the multi-plate park is used for the user side to view, and the three-dimensional model of the multi-plate park is applied to the following step 3, which is executed in a subordinate sub-step, and includes the following steps:

step 31: and (3) acquiring the assessment results of the risk levels of the subareas in the step (2), and setting the threat space range corresponding to the risk level of each subarea according to the multi-plate block subarea model.

Preferably, the safety paths generated in the step 4 are synchronously packaged and distributed to each mobile electronic device in the garden through a wireless network;

the safety path packaging file judges the position information of the mobile electronic equipment before distribution, and after the position information of the mobile electronic equipment is judged, the safety path corresponding to the park subarea is selected according to the position information of the mobile electronic equipment to carry out setting coordination before the packaging file.

By the arrangement, when the mobile electronic equipment user receives and reads the safe path packaging file, the user can know the safe path of the work site area more quickly, and the mobile electronic equipment user is prevented from finding the safe path difficultly.

Preferably, the data content collected by the monitoring device in step 5 includes: environmental temperature and humidity data, environmental gas composition parameters, equipment working state parameters and current unfinished working hour data of park workers;

the acquisition period and the feedback period of the acquired data of the monitoring equipment are set according to user definition of a user side, and the acquisition period and the feedback period are initially set to be three seconds/time and fifteen minutes/time by default;

and the data acquisition times of the monitoring equipment checked by the user side in the time threshold range of every four groups of feedback cycles are more than or equal to 1.

By the arrangement, various safety risk influence factors of the park can be comprehensively collected, so that steps and users in the method can make more accurate judgment and effective management.

Example 3

Preferably, the step 4 and the step 5 are provided with substeps comprising the steps of:

step 51: configuring a monitoring equipment signal generator, and configuring a computer to receive data acquired by real-time operation of monitoring equipment;

step 52: when the computer receives real-time operation acquisition data sent by monitoring equipment, acquiring position information of the monitoring equipment corresponding to the received acquisition data synchronously through a signal generator configured on the monitoring equipment;

step 53: and deploying audio alarms in each park zone, and performing priority triggering control on the audio alarms corresponding to the position information of the monitoring equipment according to the signal generator.

Preferably, the number of the audio alarms deployed in the subareas of the park is more than or equal to 2, and each group of audio alarms is connected with the circuit arrangement of the audio alarms.

Through the setting of this substep, can dispose the safety risk maintenance function of voice prompt mode for the garden, with the help of voice prompt to reach the prevention early warning and warn the safeguard effect that garden staff evacuated when the crisis appears.

Preferably, the audio alarm triggers logic synchronization to be sent to the data repository and stored according to the safety threshold set by the data collected by the monitoring device in step 6.

Preferably, the campus risk value calculation in step 7 is provided with an operation cycle, and the operation cycle is synchronously and coordinately set according to the collected data feedback cycle of the monitoring device, where the formula is:

；

in the formula, R is a risk superposition value showing a major hazard source in a chemical industrial park, (= 1,2, N);

the probability of accident occurrence of the 1 st major hazard source;

the 1 st major hazard source accident is the result caused by the 1 st major hazard source accident, namely the accident causes the death of personnel, and the probability value is used for representing;

FR is the fire emergency rescue coefficient;

MR is the treatment emergency rescue coefficient.

In summary, the embodiments can effectively perform regional division management on the garden, and based on the divided regions, a garden model is constructed so that a user side can perform overall management on the garden through the garden model, meanwhile, garden roads are further captured in the garden model, and then safety routes are configured for all the zones according to the safety risk degree of the garden zones, so as to ensure that garden workers can evacuate rapidly and orderly when dealing with dangerous situations; in the step execution process, the risk assessment can be carried out on the divided park partitions, so that subsequent park workers can conveniently make priority selection on the safety management of the park, and the safety risk of the park is ensured to be subjected to adaptive processing; in addition, reasonable monitoring equipment planning can be configured for the park, and in the state of configuring the monitoring equipment, a certain degree of early warning effect can be brought to workers and managers in the park through periodic data acquisition and setting and comparing of safety thresholds of the data, so that safety risk accidents are avoided as much as possible.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (10)

1. A method for quickly building a park safety risk control platform based on a low-code platform is characterized by comprising the following steps of:

step 1: analyzing the property of the park, acquiring the risk type of the park, constructing park partition logic according to the park risk type, and performing regional division on the park by applying the park partition logic;

step 2: acquiring the specific risk items of each park subarea, and evaluating the park subarea risk level according to the specific risk items of the park subareas;

and 3, step 3: acquiring park area division result data, and building a model of the multi-plate park by referring to the division result data;

and 4, step 4: capturing a park road model in the multi-plate park model, configuring the park road model with a subarea area in the multi-plate park model, and generating a safety path according to the park subarea risk level;

and 5: deploying monitoring equipment to each park partition, receiving data acquired by the monitoring equipment in real time, and synchronously configuring an acquisition cycle and a feedback cycle of the data acquired by the monitoring equipment;

and 6: setting a safety threshold value of data collected by monitoring equipment, and triggering and operating an audio alarm according to the set safety threshold value;

and 7: and calculating the risk value of the park according to the data acquired by the monitoring equipment and the set safety threshold value.

2. The method for quickly building the garden security risk management and control platform based on the low-code platform according to claim 1, wherein the property content and the risk type of the garden in the step 1 are analyzed and acquired according to the product type of the garden, the step 1 is performed to synchronously build a data repository, and the content data obtained by performing the step 1 is stored each time the method application initializes the step 1.

3. The method for quickly building the campus security risk management and control platform based on the low-code platform according to claim 1, wherein the specific events of the campus partition risk obtained in the step 2 are manually edited and set by a user or identified according to a campus product type and a product chain logic.

4. The method for quickly building the park safety risk control platform based on the low-code platform according to claim 1, wherein the multi-plate park model built in the step 3 comprises a two-dimensional model and a three-dimensional model, wherein the two-dimensional model of the multi-plate park is used for being viewed by a user, and the three-dimensional model of the multi-plate park is applied to the execution of the following subordinate sub-steps of the step 3 and comprises the following steps:

step 31: and (3) acquiring the assessment result of the park subarea risk level in the step (2), and setting the threat space range corresponding to the park subarea risk level according to the multi-plate park model.

5. The method for quickly building the garden security risk management and control platform based on the low-code platform according to claim 1, wherein the security paths generated in the step 4 are synchronously packaged and distributed to mobile electronic devices in a garden through a wireless network;

the safety path packaging file judges the position information of the mobile electronic equipment before distribution, and after the position information of the mobile electronic equipment is judged, the safety path corresponding to the park subarea is selected according to the position information of the mobile electronic equipment to carry out setting coordination before the packaging file.

6. The method for quickly building a garden safety risk control platform according to claim 1, wherein the data content collected by the monitoring device in the step 5 comprises: environmental temperature and humidity data, environmental gas composition parameters, equipment working state parameters and current unfinished working hour data of park workers;

the acquisition period and the feedback period of the acquired data of the monitoring equipment are set according to user definition of a user side, and the initial default of the acquisition period and the feedback period is set to be three seconds/time and fifteen minutes/time;

and the data acquisition times of the monitoring equipment checked by the user side in the time threshold range of every four groups of feedback cycles are more than or equal to 1.

7. The method for quickly building the garden safety risk control platform based on the low-code platform according to claim 1, wherein the step 4 and the step 5 are provided with substeps, and the method comprises the following steps:

step 51: configuring a monitoring equipment signal generator, and configuring a computer to receive data acquired by real-time operation of monitoring equipment;

step 52: when the computer receives real-time operation acquisition data sent by monitoring equipment, acquiring position information of the monitoring equipment corresponding to the received acquisition data synchronously through a signal generator configured on the monitoring equipment;

step 53: and deploying audio alarms in each park zone, and performing priority triggering control on the audio alarms corresponding to the position information of the monitoring equipment according to the signal generator.

8. The method for quickly building the garden safety risk control platform according to claim 7, wherein the number of the audio alarms deployed in the garden subareas in each subarea is greater than or equal to 2, and each group of audio alarm connection circuits are arranged in parallel.

9. The method for rapidly building the garden safety risk management and control platform based on the low-code platform according to claim 1, wherein in the step 6, the audio alarm triggers logic to synchronously send and store the logic to the data repository according to a safety threshold set by data collected by monitoring equipment.

10. The method for quickly building the park safety risk management and control platform based on the low-code platform according to claim 1, wherein the park risk value calculation in the step 7 is provided with an operation period, the operation period is synchronously coordinated and set according to a data acquisition feedback period of monitoring equipment, and the formula is as follows:

;

in the formula, R is a risk superposition value showing a major hazard source in a chemical industrial park, (= 1,2, N);

the probability of accident occurrence of the 1 st major hazard source;

the 1 st major hazard source accident is the result caused by the 1 st major hazard source accident, namely the accident causes the death of personnel, and the probability value is used for representing;

FR is the fire emergency rescue coefficient;

MR is the treatment emergency rescue coefficient.

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