CN115599051A - Light industry on duty configuration safety judgment system and method - Google Patents

Abstract

The invention discloses a light industry on duty configuration safety judgment system and a method, comprising the following steps: a monitoring module; wherein, all information includes: temperature and humidity, dust density and image photos of the monitored area; an integration module; a blending module; an early warning module; and a linkage module. The temperature and humidity and the dust density of the monitored area are monitored in real time through the monitoring module, all information of each aging of the monitored area is collected and sent, all information of each aging is recorded and stored through the integration module, abnormal signals in all information obtained by the monitored area are judged, whether early warning is needed or not is judged according to the abnormal signals, and early warning feedback is carried out through the early warning module. The early warning of the area which is easy to generate dust explosion is well realized. Meanwhile, the system is also provided with a linkage module and a blending module, and dust is sprayed and settled in advance in the early stage of dangerous case occurrence, so that dust explosion is avoided, and the safety of personnel and equipment is ensured.

Description

Light industry on duty configuration safety judgment system and method

Technical Field

The invention relates to the technical field of industrial safety, in particular to a light industry on duty configuration safety judgment system and a light industry on duty configuration safety judgment method.

Background

The light industry mainly refers to the industrial sector providing consumer goods for daily life, and takes agricultural products as raw materials. Such as cotton, wool, hemp and silk, leather and its products, paper pulp and paper, food manufacturing and other industries; is prepared from non-agricultural products. Such as daily-use metal, daily-use chemical industry, daily-use glass, daily-use ceramic, chemical fiber and its fabric, match and domestic wood product. The light industrial products are mostly consumer products, and a part of the light industrial products are used as raw materials and semi-finished products for production, such as chemical fibers, industrial cloth, paper, salt and the like. The light industry comprises the industries of household appliances, plastics, leather, hardware, furniture, cultural and miscellaneous objects, light machinery and the like.

Dust explosion is used as a common accident risk in the production process of light industry, a large amount of dust-shaped floaters are collected in a working site in the early period of explosion, when the explosion point is reached, flame is instantly spread in the whole dust mixing space, the chemical reaction speed is very high, a large amount of heat is released at the same time, very high temperature and very high pressure are formed, and the energy of the system is converted into mechanical energy and radiation of light and heat, so that the system has very strong destructive power.

Dust explosion is often accompanied with production and processing places where aluminum powder, zinc powder, aluminum material processing grinding powder, various plastic powders, intermediates of organic synthetic drugs, wheat flour, sugar, wood chips, dyes, glue wood ash, milk powder, tea powder, tobacco powder, coal dust, plant fiber dust and the like are generated. Therefore, before light industry production, safety judgment needs to be carried out on production and processing places, early warning and avoidance are carried out on areas prone to explosion, and dust explosion is avoided.

Disclosure of Invention

The invention aims to provide a light industry on duty configuration safety judgment system and method for early warning and avoiding of areas prone to dust explosion in advance.

In order to achieve the purpose, the invention adopts the following technical scheme:

one aspect of the present invention provides a light industry job-running configuration safety determination system, including:

the monitoring module is arranged in the monitored area and is used for collecting and monitoring all information of the monitored area;

wherein the total information includes: temperature and humidity, dust density and image photos of the monitored area;

the integrated module is interactively connected with the monitoring module, acquires all information of the monitoring module, records and stores all the information, judges abnormal signals in all the information of each time effectiveness and generates an integrated allocation signal;

the allocation module is interactively connected with the integration module, acquires the integration allocation signal, and performs pre-linkage allocation with a fire extinguishing system in a detected area to generate an early warning signal;

the early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning;

and the linkage module is used for man-machine interaction and controlling the allocation module to perform linkage allocation with the fire extinguishing system in the detected area.

In some embodiments, the monitoring module comprises:

the temperature and humidity monitoring unit is used for monitoring the temperature and humidity of the monitored area to acquire environment temperature and humidity information of the monitored area;

the dust monitoring unit is used for monitoring the dust content of the monitored area to acquire the dust density information of the monitored area;

the camera monitoring unit is used for monitoring the real-time image of the monitored area and acquiring the real-time image information of the monitored area;

the information transmission unit is respectively connected with the temperature and humidity monitoring unit, the dust monitoring unit and the camera shooting monitoring unit in an interactive mode, the information transmission unit obtains environment temperature and humidity information of the monitored area, dust density information of the monitored area and real-time image information of the monitored area, and all information of the monitored area is generated.

In some embodiments, the integrated module comprises:

the information acquisition unit is interactively connected with the information transmission unit and acquires all information of the monitored area;

the information judgment unit is interactively connected with the information acquisition unit, early warning threshold information is arranged in the information judgment unit, and the information judgment unit compares the early warning threshold information with all information of the monitored area to judge and acquire abnormal signals in all aged information;

and the control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit and generates an integrated allocation signal.

In some embodiments, the pre-alarm threshold information comprises:

dust density explosion critical threshold and temperature and humidity explosion critical threshold.

In some embodiments, the fire suppression system includes at least one fire spray unit, the deployment module includes:

the allocation acquisition unit is interactively connected with the control output unit and acquires an integrated allocation signal;

the control allocation unit is interactively connected with the allocation acquisition unit, acquires the integrated allocation signal, sends an allocation instruction and generates an early warning signal;

and the allocation exercise unit is interactively connected with the control allocation unit, and acquires the allocation instruction and performs preview linkage with the spraying units.

In some embodiments, the early warning module comprises:

and the alarm is in interactive connection with the control allocation unit, acquires the early warning signal and simultaneously gives out early warning.

In another aspect, the present invention provides a light industry shift configuration security determination method, which adopts the light industry shift configuration security determination system described above, and the determination method includes:

s1, a monitoring module acquires all information with timeliness of a monitored area in real time;

s2, an integration module is in interactive connection with the monitoring module, the integration module acquires all information with time effect of the monitored area, records and judges abnormal signals in all information of the time effect, and generates an integrated allocation signal;

s3, a deployment module is in interactive connection with the integrated module, acquires an integrated deployment signal, sends a corresponding instruction according to the integrated deployment signal, performs pre-linkage deployment with a fire extinguishing system in the detected area, and generates an early warning signal;

s4, the early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning;

and S5, after receiving the early warning, the personnel controls the allocation module to acquire the image photo of the monitored area in real time through the linkage module, and simultaneously controls the allocation module to perform linkage allocation with a fire extinguishing system of the monitored area to perform spraying and settling on dust in advance.

In some embodiments, S2 includes:

s21, the information acquisition unit acquires all information of the monitored area in different time periods, and generates and records all information with aging;

s22, an information judgment unit is interactively connected with the information acquisition unit and acquires all information with time effect;

s23, comparing the early warning threshold information with all the information of the monitored area by the information judgment unit, and judging and acquiring abnormal signals in all the aging information;

and S24, the control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit, judges whether the advance intervention is needed or not, and generates an integrated allocation signal.

In some embodiments, the warning threshold information in S23 includes:

a: critical explosion threshold of dust density, b: critical threshold value of temperature and humidity explosion;

the dust density in all the information of the nth aging is defined as: an;

the temperature and humidity in all the information of the nth aging are defined as follows: bn;

at this time, a ₁ ··a _n All are less than a, otherwise, the signals are abnormal dust density signals;

at this time, b ₁ ··b _n If the temperature and humidity are all smaller than b, otherwise, the temperature and humidity are abnormal signals.

In some embodiments, the abnormal signal determination method in S23 further includes:

b is to be _nT Temperature values in the overall information representing the nth aging, b _XT Temperature values in the overall information representing the preceding Xth aging of n, b _nT -b _XT<5℃ And n-X is more than or equal to 3min and less than or equal to 6min, otherwise, the temperature abnormal signal is judged;

b is to _nH Humidity value in the entire information representing the nth aging, b _XH Humidity value in all information representing the preceding X aging of n, b _XT -b _nT<3 % RH, and n-X is more than or equal to 3min and less than or equal to 6min, otherwise, judging as a humidity abnormal signal.

The invention has the beneficial effects that:

in the embodiment of the invention, the temperature and humidity and the dust density of the monitored area are monitored in real time through the monitoring module, all the information of each aging of the monitored area is acquired and sent, all the information of each aging is recorded and stored by the integration module, abnormal signals in all the information acquired by the monitored area are judged, and early warning feedback is carried out through the early warning module according to the judgment of whether early warning is needed or not. The early warning of the area which is easy to generate dust explosion is well realized. Simultaneously this system has still set up linkage module and allotment module, takes place earlier stage at the dangerous situation, and personnel acquire the image photo of monitored area in real time through linkage module control allotment module, and the fire extinguishing systems who controls allotment module and detected the region simultaneously carries out the linkage allotment, sprays the settlement to the dust in advance, realizes stopping dust explosion's emergence, has guaranteed the safety of personnel and equipment.

Drawings

Fig. 1 is a schematic structural diagram of a system of a light industry job-starting configuration security determination system according to an embodiment of the present invention;

fig. 2 is a schematic flow chart of a light industry on duty configuration security determination method provided in an embodiment of the present invention;

fig. 3 is a schematic flow diagram of S2 of a method for determining security of light industry job-starting configuration according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive step based on the embodiments of the present invention, are within the scope of protection of the present invention.

It should be noted that all directional indicators (such as up, down, left, right, front, back \8230;) in the embodiments of the present invention are only used to explain the relative positional relationship between the components, the motion situation, etc. in a specific posture (as shown in the attached drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be interconnected within two elements or in a relationship where two elements interact with each other unless otherwise specifically limited. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout includes three juxtapositions, exemplified by "A and/or B" including either A or B or both A and B. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Example one

Referring to fig. 1, on one hand, the invention provides a light industry post configuration safety judgment system, which monitors the temperature and humidity and dust density of a monitored area in real time through a monitoring module, collects and sends all aging information of the monitored area, records and stores all aging information through an integrated module, judges abnormal signals in all information acquired by the monitored area, and performs early warning feedback through an early warning module according to the judgment whether early warning is needed or not. The early warning of the area which is easy to generate dust explosion is well realized in advance. Simultaneously this system has still set up linkage module and allotment module, takes place earlier stage at the dangerous situation, and personnel acquire in real time by monitoring the regional image photo through linkage module control allotment module, and the simultaneous control allotment module carries out the linkage allotment with the fire extinguishing systems who is detected the region, sprays the settlement to the dust in advance, realizes stopping dust explosion's emergence, has guaranteed the safety of personnel and equipment.

Specifically, the safety determination system includes: the system comprises a monitoring module, an integration module, a deployment module, an early warning module and a linkage module. The monitoring module is arranged in a monitored area and is used for collecting and monitoring temperature and humidity, dust density and image pictures in the monitored area so as to generate all information. I.e. the total information comprises: the humiture, dust density, image photo of monitored area. The integrated module is interactively connected with the monitoring module, acquires all information of the monitoring module, records and stores all the information, judges abnormal signals in all the aging information and generates an integrated allocation signal. The integrated module judges and identifies all acquired information in the monitored area, and judges abnormal signals before dangerous situations of the monitored area occur, so that early warning is realized, and a corresponding instruction is sent to carry out early warning reminding and evading in advance. The allocation module is interactively connected with the integrated module, acquires the integrated allocation signal, and is in pre-linkage allocation with a fire extinguishing system in a detected area to generate an early warning signal. The deployment module acquires integrated deployment signal, obtains and is surveyed regional fire extinguishing system rehearsal instruction, carries out linkage deployment in advance with the fire extinguishing system who is surveyed the region to can avoid the dangerous situation fast after the dangerous situation takes place. The early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning. The early warning module acquires the early warning signal of the allocation module, and early warning is carried out on personnel in advance, so that the personnel can know that the dangerous case is about to occur in advance, and the follow-up early warning avoiding work for manually controlling the dangerous case is facilitated. The linkage module is used for man-machine interaction, and controls the allocation module to be in linkage allocation with the fire extinguishing system in the detected area. In this embodiment, the safety determination system monitors the temperature and humidity and the dust density of the monitored area in real time through the monitoring module, collects and sends all aging information of the monitored area, records and stores all aging information through the integration module, determines abnormal signals in all information acquired by the monitored area, and performs early warning feedback through the early warning module according to the abnormal signals. The early warning of the area which is easy to generate dust explosion is well realized. Simultaneously this system has still set up linkage module and allotment module, takes place earlier stage at the dangerous situation, and personnel acquire in real time by monitoring the regional image photo through linkage module control allotment module, and the simultaneous control allotment module carries out the linkage allotment with the fire extinguishing systems who is detected the region, sprays the settlement to the dust in advance, realizes stopping dust explosion's emergence, has guaranteed the safety of personnel and equipment.

In this embodiment, the monitoring module includes: humiture monitoring unit, dust monitoring unit, the information transport unit of making a video recording, humiture monitoring unit is used for monitoring the humiture of monitored area, obtains the environment humiture information of monitored area. The dust monitoring unit is used for monitoring the dust content of the monitored area and acquiring the dust density information of the monitored area. The camera monitoring unit is used for monitoring the real-time image of the monitored area and acquiring the real-time image information of the monitored area. The information conveying unit is respectively connected with the temperature and humidity monitoring unit, the dust monitoring unit and the camera shooting monitoring unit in an interactive mode, the information conveying unit obtains environment temperature and humidity information of the monitored area, dust density information of the monitored area and real-time image information of the monitored area, and all information of the monitored area is generated.

In a possible embodiment, the temperature and humidity monitoring unit includes at least one set of temperature and humidity monitoring meters, and is configured to monitor temperature and humidity of the monitored area. The dust density monitoring unit comprises at least one group of dust density sensors or photosensitive sensors and is used for monitoring the dust density in a monitored area. The camera shooting monitoring unit comprises at least one group of monitoring cameras and is used for monitoring the monitored area in real time. The environment temperature and humidity information of the monitored area, the dust density information of the monitored area and the real-time image information of the monitored area are monitored and collected in real time, and all information of the monitored area is generated.

In this embodiment, the integrated module includes: the device comprises an information acquisition unit, an information judgment unit and a control output unit. The information acquisition unit is interactively connected with the information transmission unit, and the information acquisition unit acquires all information of the monitored area. The information judgment unit is interactively connected with the information acquisition unit, early warning threshold information is arranged in the information judgment unit, and the information judgment unit compares the early warning threshold information with all information of the monitored area to judge and acquire abnormal signals in all aged information. The control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit and generates an integrated allocation signal. It should be noted that, in this embodiment, the early warning threshold information includes: dust density explosion critical threshold and temperature and humidity explosion critical threshold. Namely, if the temperature, humidity and dust density of the monitored area obtained by the monitoring module exceed the preset dust density explosion critical threshold and temperature and humidity explosion critical threshold, the situation abnormal signal of the monitored area is judged to be sent out, and an integrated allocation signal is generated.

In this embodiment, in order to ensure the early warning evasion effect of the fire extinguishing system, the fire extinguishing system comprises at least one fire spray unit.

In this embodiment, the allocating module includes: the device comprises a deployment acquisition unit, a control deployment unit and a deployment exercise unit. The allocation obtaining unit is interactively connected with the control output unit, and the allocation obtaining unit obtains the integrated allocation signal. The control allocation unit is interactively connected with the allocation acquisition unit, acquires the integrated allocation signal, sends an allocation instruction and generates an early warning signal at the same time. The allocation exercise unit is interactively connected with the control allocation unit, and acquires the allocation instruction and performs preview linkage with the spraying units.

In some embodiments, the early warning module comprises: and the alarm is interactively connected with the control allocation unit and acquires the early warning signal and simultaneously sends out early warning. Preferably, the alarm is a buzzer alarm, and the buzzer alarm can acquire an early warning signal and send out a buzzer for early warning.

Example two

Referring to fig. 1-3, another aspect of the present invention provides a light industry job-starting configuration security determination method, where the light industry job-starting configuration security determination system described above is used, and the determination method includes:

s1, a monitoring module acquires all information with timeliness of a monitored area in real time; namely, the safety judgment system monitors the temperature, the humidity and the dust density of the monitored area in real time through the monitoring module.

S2, an integration module is in interactive connection with the monitoring module, the integration module acquires all information with time effect of the monitored area, records and judges abnormal signals in all information of the time effect, and generates an integrated allocation signal; the integration module records and stores all the information of each time effect, judges abnormal signals in all the information acquired by the monitored area, and performs early warning feedback through the early warning module according to the judgment whether early warning is needed or not.

S3, a deployment module is in interactive connection with the integrated module, acquires an integrated deployment signal, sends a corresponding instruction according to the integrated deployment signal, performs pre-linkage deployment with a fire extinguishing system in the detected area, and generates an early warning signal; the control allocation unit is interactively connected with the allocation acquisition unit, acquires the integrated allocation signal, sends an allocation instruction and simultaneously generates an early warning signal. The allocation exercise unit is interactively connected with the control allocation unit, and acquires the allocation instruction and performs preview linkage with the spraying units.

S4, the early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning;

and S5, after receiving the early warning, the personnel control the allocation module to acquire the image photos of the monitored area in real time through the linkage module, and simultaneously control the allocation module to perform linkage allocation with a fire extinguishing system of the monitored area, and spray and settle dust in advance.

In this embodiment, to further refine the operation of the integration module, specifically, S2 includes:

s21, the information acquisition unit acquires all information of the monitored area in different time periods, and generates and records all information with timeliness;

s22, an information judgment unit is interactively connected with the information acquisition unit and acquires all information with time effect;

s23, the information judgment unit compares the self early warning threshold information with all the information of the monitored area, and judges and acquires abnormal signals in all the aging information; namely, if the acquired temperature, humidity and dust density of the monitored area exceed the predetermined dust density explosion critical threshold and temperature, humidity and explosion critical threshold, the situation abnormal signal of the monitored area is judged to be sent out.

And S24, the control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit, judges whether the advance intervention is needed or not, and generates an integrated allocation signal. Namely, the judging unit judges abnormal signals in all information acquired by the monitored area by using the preset early warning threshold information, and judges whether early warning is needed or not according to the abnormal signals.

In this embodiment, the early warning threshold information in S23 includes: a: critical explosion threshold of dust density, b: critical threshold value of temperature and humidity explosion; the dust density in all the information of the nth aging is defined as: an; the temperature and humidity in all the information of the nth aging are defined as follows: bn; at this time, a ₁ ··a _n All are less than a, otherwise, the signals are abnormal dust density signals; at this time, b ₁ ··b _n If the temperature and humidity are all smaller than b, otherwise, the temperature and humidity are abnormal signals. That is, in this embodiment, if the acquired temperature, humidity and dust density of the monitored area exceed the predetermined dust density explosion critical threshold and temperature and humidity explosion critical threshold, it is determined that the abnormal condition signal of the monitored area is sent out.

In this embodiment, in order to further ensure the accuracy of determining the abnormality of the condition, the abnormality signal determining method in S23 further includes:

b is to _nT Temperature values in the entire information representing the nth aging, b _XT Temperature values in the entire information representing the Xth aging before n, b _nT -b _XT<5℃ And n-X is more than or equal to 3min and less than or equal to 6min, otherwise, the temperature is judged to be an abnormal signal. Namely, the temperature difference between the front and the back does not exceed 5 ℃ in the difference of 3min (min) to 6min (min), otherwise, the temperature is judged to be a temperature abnormal signal.

B is to _nH Humidity value in the entire information representing the nth aging, b _XH Humidity values in the complete information representing the X aging before n, b _XT -b _nT<3 % RH, and n-X is more than or equal to 3min (min) and less than or equal to 6min (min), otherwise, judging as a humidity abnormal signal. That is, even in a difference of 3 minutes to 6 minutes, the difference in the front and rear humidity should not exceed 3% RH (the percentage of the saturated water vapor amount in the air is 3% in the case where the water vapor amount contained in the air is the same as that of the air).

It should be noted that the preset values in the early warning threshold information may be set according to actual application scenarios, which is not summarized here.

Additionally, unless explicitly recited in the claims, the order of processing elements and sequences, use of numbers and letters, or use of other designations in this application is not intended to limit the order of the processes and methods in this application. While various presently contemplated embodiments of the invention have been discussed in the foregoing disclosure by way of example, it is to be understood that such detail is solely for that purpose and that the appended claims are not limited to the disclosed embodiments, but, on the contrary, are intended to cover all modifications and equivalent arrangements that are within the spirit and scope of the embodiments herein. For example, although the system components described above may be implemented by hardware devices, they may also be implemented by software-only solutions, such as installing the described system on an existing server or mobile device.

Similarly, it should be noted that in the preceding description of embodiments of the application, various features are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure aiding in the understanding of one or more of the embodiments. This method of disclosure, however, is not intended to imply that more features are required than are expressly recited in the claims. Indeed, the embodiments may be characterized as having less than all of the features of a single embodiment disclosed above.

Numerals describing the number of components, attributes, etc. are used in some embodiments, it being understood that such numerals used in the description of the embodiments are modified in some instances by the use of the modifier "about", "approximately" or "substantially". Unless otherwise indicated, "about", "approximately" or "substantially" indicates that the number allows a variation of ± 20%. Accordingly, in some embodiments, the numerical parameters set forth in the specification and claims are approximations that may vary depending upon the desired properties sought to be obtained by a particular embodiment. In some embodiments, the numerical parameter should take into account the specified significant digits and employ a general digit-preserving approach. Notwithstanding that the numerical ranges and parameters setting forth the broad scope of the range are approximations, in the specific examples, such numerical values are set forth as precisely as possible within the scope of the application.

Each patent, patent application publication, and other material, such as articles, books, specifications, publications, documents, and the like, cited in this application is hereby incorporated by reference in its entirety. Except where the application is filed in a manner inconsistent or contrary to the present disclosure, and except where the claim is filed in its broadest scope (whether present or later appended to the application) as well. It is noted that the descriptions, definitions and/or use of terms in this application shall control if they are inconsistent or contrary to the present disclosure.

Finally, it should be understood that the embodiments described herein are merely illustrative of the principles of the embodiments of the present application. Other variations are also possible within the scope of the present application. Thus, by way of example, and not limitation, alternative configurations of the embodiments of the present application can be viewed as being consistent with the teachings of the present application. Accordingly, the embodiments of the present application are not limited to only those explicitly described and illustrated herein.

Claims (10)

1. A light industry post configuration safety judgment system is characterized by comprising:

the monitoring module is arranged in the monitored area and is used for collecting and monitoring all information of the monitored area;

wherein the total information includes: temperature and humidity, dust density and image photos of the monitored area;

the integrated module is interactively connected with the monitoring module, acquires all information of the monitoring module, records and stores all the information, judges abnormal signals in all the aging information and generates an integrated allocation signal;

the allocation module is interactively connected with the integration module, acquires the integration allocation signal, and performs pre-linkage allocation with a fire extinguishing system in a detected area to generate an early warning signal;

the early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning;

and the linkage module is used for man-machine interaction and controlling the allocation module to perform linkage allocation with the fire extinguishing system in the detected area.

2. The light industry job-completion configuration safety decision system according to claim 1, wherein said monitoring module comprises:

the temperature and humidity monitoring unit is used for monitoring the temperature and humidity of the monitored area to acquire environment temperature and humidity information of the monitored area;

the dust monitoring unit is used for monitoring the dust content of the monitored area to acquire the dust density information of the monitored area;

the camera monitoring unit is used for monitoring the real-time image of the monitored area and acquiring the real-time image information of the monitored area;

the information transmission unit is respectively connected with the temperature and humidity monitoring unit, the dust monitoring unit and the camera shooting monitoring unit in an interactive mode, the information transmission unit obtains environment temperature and humidity information of the monitored area, dust density information of the monitored area and real-time image information of the monitored area, and all information of the monitored area is generated.

3. The light industry job-starting configuration security decision system according to claim 2, wherein said integration module comprises:

the information acquisition unit is interactively connected with the information transmission unit and acquires all information of the monitored area;

the information judgment unit is interactively connected with the information acquisition unit, early warning threshold information is arranged in the information judgment unit, and the information judgment unit compares the early warning threshold information with all information of the monitored area to judge and acquire abnormal signals in all aged information;

and the control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit and generates an integrated allocation signal.

4. The light industry job-completion configuration safety decision system according to claim 3, wherein the early warning threshold information comprises:

dust density explosion critical threshold and temperature and humidity explosion critical threshold.

5. The light industry job-configuration safety decision system of claim 4, wherein the fire extinguishing system comprises at least one fire sprinkler unit, the deployment module comprises:

the allocation acquisition unit is interactively connected with the control output unit and acquires an integrated allocation signal;

the control allocation unit is interactively connected with the allocation acquisition unit, acquires the integrated allocation signal, sends an allocation instruction and generates an early warning signal;

and the allocation exercise unit is connected with the control allocation unit in an interactive manner, and acquires the allocation instruction and performs preview linkage with the plurality of spraying units.

6. The light industry job-completion configuration safety decision system according to claim 5, wherein the early warning module comprises:

and the alarm is interactively connected with the control allocation unit and acquires the early warning signal and simultaneously sends out early warning.

7. A light industry job configuration security judgment method, the light industry job configuration security judgment system according to any one of claims 1 to 6, the judgment method comprising:

s1, a monitoring module acquires all information with timeliness of a monitored area in real time;

s2, an integration module is in interactive connection with the monitoring module, the integration module acquires all information with time effect of the monitored area, records and judges abnormal signals in all information of the time effect, and generates an integrated allocation signal;

s3, a deployment module is in interactive connection with the integrated module, acquires an integrated deployment signal, sends a corresponding instruction according to the integrated deployment signal, performs pre-linkage deployment with a fire extinguishing system in the detected area, and generates an early warning signal;

s4, the early warning module is interactively connected with the allocation module, acquires the early warning signal and sends out early warning;

and S5, after receiving the early warning, the personnel controls the allocation module to acquire the image photo of the monitored area in real time through the linkage module, and simultaneously controls the allocation module to perform linkage allocation with a fire extinguishing system of the monitored area to perform spraying and settling on dust in advance.

8. The method for determining the safety of the light industry post configuration according to claim 7, wherein the step S2 comprises:

s21, the information acquisition unit acquires all information of the monitored area in different time periods, and generates and records all information with aging;

s22, an information judgment unit is interactively connected with the information acquisition unit and acquires all information with time effect;

s23, the information judgment unit compares the self early warning threshold information with all the information of the monitored area, and judges and acquires abnormal signals in all the aging information;

and S24, the control output unit is interactively connected with the information judgment unit, acquires abnormal signals in all the information acquired by the information judgment unit, judges whether the advance intervention is needed or not, and generates an integrated allocation signal.

9. The method for determining the safety of the light industry post configuration according to claim 8, wherein the early warning threshold information in S23 includes:

a: critical explosion threshold of dust density, b: critical threshold value of temperature and humidity explosion;

the dust density in all the information of the nth aging is defined as: an;

the temperature and humidity in all the information of the nth aging are defined as follows: bn;

at this time, a ₁ ··a _n All are less than a, otherwise, the signals are abnormal dust density signals;

at this time, b ₁ ··b _n If the temperature and the humidity are all smaller than b, otherwise, the signals are temperature and humidity abnormal signals.

10. The method for determining the safety of the light industry post configuration according to claim 9, wherein the method for determining the abnormal signal in S23 further comprises:

b is to _nT Temperature values in the overall information representing the nth aging, b _XT Temperature values in the entire information representing the Xth aging before n, b _nT -b _XT<5℃ And n-X is more than or equal to 3min and less than or equal to 6min, otherwise, judging the temperature is abnormal;

b is to be _nH Humidity value in the entire information representing the nth aging, b _XH Humidity value in all information representing the preceding X aging of n, b _XT -b _nT<3 % RH, and n-X is more than or equal to 3min and less than or equal to 6min, otherwise, judging as a humidity abnormal signal.

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