CN112650330A - Factory workshop emergency lighting intelligent control system - Google Patents

Abstract

The invention discloses an intelligent control system for emergency lighting of a factory workshop, belonging to the field of emergency lighting; relates to an emergency lighting intelligent control technology; the emergency evacuation route control system is used for solving the problem that the emergency evacuation route cannot be distinguished through the brightness of light in the existing emergency lighting intelligent control system; the mode judgment module is used for acquiring the numerical value of personnel in the factory workshop in the personnel distribution information in the factory workshop, so that under the condition that no working personnel exist in the factory workshop, an emergency lighting intelligent control system is not required to be activated in an emergency situation, and energy waste is avoided; carry out intelligent emergency circuit planning with staff distribution area value through the circuit planning module, thereby avoided the personnel that the personnel are chaotic under the crisis condition and the problem that the efficiency is low that flees that causes, can realize emergency circuit planning better through the electronic map model, when taking place emergency, the staff can then discover the emergency circuit of emergent fleing through the change of light.

Description

Factory workshop emergency lighting intelligent control system

Technical Field

The invention belongs to the field of emergency lighting; relates to an emergency lighting intelligent control technology; in particular to an intelligent control system for emergency lighting in factory workshops.

Background

The fire disaster is one of the most frequent disasters in the modern society, and seriously threatens the life and property safety of people. Building forestation and personnel concentration in cities, once a fire disaster causes serious harm, the fire prevention and rescue of factory workshop buildings are the most main work in a fire-fighting system, a map is used as the most intuitive expression form of urban comprehensive information, irreplaceable effects exist in the aspects of disaster positioning, route planning, crowd isolation and evacuation, rescue resource distribution, fire-fighting force planning and the like in daily fire-fighting patrol inspection and fire rescue, and detailed and accurate map information has great influence on the fire rescue in seconds, so that the map is an important subject of map application in the field of fire fighting, especially the rapid development of smart cities in recent years, the rapid popularization of basic facilities such as sensors, wireless communication networks and the like, but the development speed of the map of the subject of smart fire fighting is far behind the development of a sensing network, thereby make the map can not bear current influence fire rescue towards wisdom fire control special topic information, when the emergency takes place in the factory workshop simultaneously, the scene is chaotic, and people of work in the factory workshop can't effectual organization get up and withdraw rapidly, also can't distinguish emergent route of withdrawing through light and shade simultaneously.

Disclosure of Invention

The invention aims to provide an intelligent factory workshop emergency lighting control system, which is used for solving the problem that emergency evacuation routes cannot be distinguished through the brightness of lamplight in the existing intelligent emergency lighting control system.

The purpose of the invention can be realized by the following technical scheme:

an intelligent control system for emergency lighting of a factory workshop comprises a control module, a line planning module, a mode judging module, a signal acquisition module and a communication module;

the signal acquisition module is used for acquiring personnel distribution information in a factory workshop, illumination information in the factory workshop and emergency signal information;

the emergency signal information comprises a gas concentration value, a smoke concentration value, a temperature value and a humidity value which are obtained in a factory workshop, and overproof data in the gas concentration value, the smoke concentration value, the temperature value and the humidity value are extracted and marked as abnormal data values;

when any one of the gas concentration value, the smoke concentration value, the temperature value and the humidity value generates an abnormal data value, emergency signal information is generated and transmitted into the mode judgment module through the communication module;

when the mode judging module receives the emergency signal information, the communication module acquires the personnel distribution information in the factory workshop and the illumination information in the factory workshop which are acquired in the signal acquisition module in real time, and substitutes the information into the judging model to carry out intelligent judgment, and the judging process of the mode judging module is as follows:

the method comprises the following steps: acquiring the numerical value of personnel in the factory workshop in the personnel distribution information in the factory workshop;

step two: when the number of the personnel in the workshop of the factory is more than 1, performing the fourth step; if the number of the personnel in the factory workshop is less than 1, performing the third step;

step three: judging that the factory workshop is in an unmanned mode at the moment, and generating an unmanned signal;

step four: judging that the factory workshop is in a manned mode at the moment, generating manned signals, and respectively transmitting the manned signals and the unmanned signals to the control module and the circuit planning module through the communication module;

the line planning module is used for planning an emergency escape line; the control module is used for controlling emergency lighting lamps in a factory workshop.

Furthermore, after receiving the person signal, the line planning module establishes data connection with the signal acquisition module through the communication module to acquire positioning data in the signal acquisition module, and substitutes the positioning data into the electronic map model to acquire a staff distribution area value;

marking the factory workshop with the employee distribution area value larger than K45 as a rejection emergency line;

marking the factory workshop with the employee distribution area value larger than K20 and the employee distribution area value smaller than K45 as a transit emergency line;

marking the factory workshop with the employee distribution area value less than K20 as a preferred emergency line;

the K45 and the K20 are both preset values;

indoor road networks among factory workshops of the preferred emergency lines are connected together to form a preferred emergency escape road network, and the preferred emergency escape road network is connected with emergency channels;

the corresponding factory workshop mark of transfer emergency circuit is i, carries out the emergent circuit classification of transfer through acquireing the interior hazardous articles quantity of factory workshop, specifically is:

b1: acquiring the quantity of dangerous goods in an electronic map model of the plant workshop corresponding to the transfer emergency line, and marking the quantity of the dangerous goods as Xi, wherein Xi is 1, 2, 3 … … n, and Xi represents the quantity of the dangerous goods in the plant workshop corresponding to the transfer emergency line;

b2: when Xi is larger than 15, marking the corresponding transfer emergency line as an independent transfer emergency line;

b3: when Xi is less than or equal to 15, the corresponding transit emergency line mark is unchanged;

the independent transfer emergency lines cannot be connected with each other, and can only be connected with a preferred emergency escape road network independently;

the transfer emergency lines are connected with one another to form a transfer emergency escape road network and are connected with a preferred emergency escape road network;

the rejection emergency lines can only be connected with a preferred emergency escape road network independently;

the emergency escape line network is composed of the rejection emergency line, the transfer emergency escape road network, the independent transfer emergency line and the optimal emergency escape road network, and the emergency escape line network is sent to the control module through the communication module.

Further, the staff distribution area value is specifically to mark the positioning data in the electronic map model, and accumulate the numerical value of the marked positioning data to finally obtain the staff distribution area value.

Further, after receiving the emergency escape line network, the control module substitutes coordinate information in the emergency escape line network into the electronic map model to obtain the escape line network of the electronic map model;

acquiring illumination information on a path of the electronic map model escape line network, and adjusting the open-close state of an illumination type line in the illumination information into a closed state;

and adjusting the open-close state of the illumination type line outside the path of the electronic map model escape line network into an open-circuit state.

Furthermore, the control module is also used for controlling the emergency indicator light circuit to be opened and closed, and when the control module receives the emergency escape circuit network, the control module adjusts the emergency indicator light circuit to be in a closed state.

Further, the specific construction method of the electronic map model comprises the following steps:

p1: obtaining building elements; the building elements include building structures, building spaces, building components, fire-fighting facilities, dangerous goods, and indoor road networks, and each of the building elements includes a set number of types;

p2: acquiring building construction drawing data of a factory workshop, and converting the building construction drawing data into vector map data;

p3: and carrying out map symbol configuration on map elements in the electronic map model by combining the vector map data to generate the electronic map model.

Further, the building structure comprises a masonry structure, a frame structure, a shear wall structure, a frame shear wall structure, a barrel structure, a bent structure and a large-span structure;

the types of the building spaces comprise a surrounding space, a horizontal communication space, a vertical communication space and an open space;

the building component comprises a bearing part, a partition part and a communication part;

the fire-fighting facilities comprise a fire alarm system, a water fire-extinguishing system, a gas fire-extinguishing system, a fire-prevention smoke-discharging system, a fire-prevention separation system and an evacuation indication system;

the dangerous goods comprise explosives, flammable gas, flammable liquid, flammable solid, oxidant, over-oxidant, corrosive and radioactive goods;

the indoor road network comprises center lines of corridors and passageways.

Further, the process of converting the construction drawing data into the vector map data includes:

a1: deleting data which are not used for constructing an indoor map in the building construction drawing data;

a2: performing coordinate conversion and re-projection on the deleted building construction drawing data according to the indoor map model;

a3: extracting wall lines, doors, windows, columns, pipelines and fire-fighting elements of the building from the building construction drawing data subjected to coordinate conversion and re-projection, and then generating a closed space surface according to an extraction result;

a4: configuring attribute data for the wall lines, doors, windows, columns, pipelines, and fire elements.

Further, gather personnel distribution information in the workshop of mill specifically do, the locator need be worn to personnel in the workshop of mill when getting into the mill, install the locating signal receiver in the workshop of mill, the locating signal receiver is used for receiving locator real-time transmission's locating data, the locator number is personnel quantity in the workshop of mill at most.

Further, the acquiring of the illumination information in the workshop specifically includes acquiring real-time circuit system data in the workshop, where the real-time circuit system data in the workshop includes the number of circuit lines in the workshop, the types of the circuits in the workshop, and the on-off states of different types of circuits in the workshop, and acquiring the illumination information in the workshop by acquiring the circuits of which the types of the circuits in the workshop are illumination types and the on-off states of the illumination type circuits.

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

acquiring the number of personnel in the factory workshop in the personnel distribution information of the factory workshop through a mode judging module, judging that the factory workshop is in a manned mode at the moment when the number of the personnel in the factory workshop is more than 1, and respectively transmitting the manned mode to a control module and a circuit planning module through a communication module; if the number of the staff in the factory workshop is less than 1, the factory workshop is judged to be in an unmanned mode at the moment, the staff in the factory workshop can be conveniently judged through the mode judgment module, and further under the condition that the factory workshop has no staff, an emergency lighting intelligent control system does not need to be activated when an emergency occurs, so that energy waste is avoided;

the factory workshop with the employee distribution area value larger than K45 is marked as a rejection emergency line through the line planning module, the factory workshop with the employee distribution area value larger than K20 and the employee distribution area value smaller than K45 is marked as a transit emergency line, and the factory workshop with the employee distribution area value smaller than K20 is marked as a preferred emergency line, so that under the condition that working employees exist in the factory workshop, intelligent emergency line planning can be carried out through the line planning module, and the problem that personnel escape efficiency is low due to confusion of the staff under the condition of crisis is solved;

emergency route planning can be better realized through the electronic map model;

the method comprises the steps that coordinate information in an emergency escape line network is substituted into an electronic map model through a control module to obtain the electronic map model escape line network, illumination information on a path of the electronic map model escape line network is obtained, the open-close state of an illumination type line in the illumination information is adjusted to be a closed state, the open-close state of the illumination type line outside the path of the electronic map model escape line network is adjusted to be an open state, so that when an emergency occurs, a worker can find the emergency line for emergency escape through the change of light, and only an emergency lamp corresponding to the emergency line for escape is turned on, so that emergency power is saved;

meanwhile, by acquiring building elements including building structures, building spaces, building components, fire-fighting facilities, dangerous goods and indoor road networks, and each of the building elements including a set number of types, obtaining the construction CAD drawing data of a factory workshop, converting the construction drawing data into vector map data, carrying out map symbol configuration on map elements in the electronic map model by combining the vector map data to generate the electronic map model, so that the fire emergency department can remotely determine the rescue direction and target through the personnel positioning information on the electronic map model, meanwhile, the electronic map model can also provide technical support for rescue, solves the problem that the development speed of the intelligent fire-fighting thematic map is far behind the development of a sensing network, therefore, the map can not bear the existing intelligent fire-fighting thematic information, and the problem of influencing fire rescue is solved.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings. Fig. 1 is a schematic block diagram of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings of the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Thus, the detailed description of the embodiments of the present invention provided in the following drawings is not intended to limit the scope of the invention as claimed, but is merely representative of selected embodiments of the invention.

As shown in fig. 1, an intelligent control system for emergency lighting in a factory workshop comprises a control module, a line planning module, a mode judgment module, a signal acquisition module and a communication module;

the signal acquisition module is used for acquiring personnel distribution information in a factory workshop, illumination information in the factory workshop and emergency signal information;

the method comprises the steps of collecting personnel distribution information in a factory workshop, wherein a positioner needs to be worn by personnel in the factory workshop when the personnel enter a factory, a positioning signal receiver is arranged in the factory workshop and used for receiving positioning data transmitted by the positioner in real time, and the number of the positioners is at most the number of the personnel in the factory workshop;

acquiring illumination information in a workshop specifically, acquiring real-time circuit system data in the workshop, wherein the real-time circuit system data in the workshop comprises the number of circuit lines in the workshop, the types of circuits in the workshop and the open-close states of different types of circuits in the workshop, and acquiring the illumination information in the workshop by acquiring the circuits with the illumination type in the workshop and the open-close states of the illumination type circuits;

acquiring emergency signal information, namely acquiring a gas concentration value, a smoke concentration value, a temperature value and a humidity value in a factory workshop, extracting overproof data in the gas concentration value, the smoke concentration value, the temperature value and the humidity value, and marking the overproof data as an abnormal data value; when any one of the gas concentration value, the smoke concentration value, the temperature value and the humidity value generates an abnormal data value, emergency signal information is generated and transmitted into the mode judging module through the communication module;

when the mode judging module receives the emergency signal information, the communication module acquires the personnel distribution information in the factory workshop and the illumination information in the factory workshop which are acquired in the signal acquisition module in real time, and substitutes the information into the judgment model to carry out intelligent judgment, and the judgment process of the mode judging module is as follows:

the method comprises the following steps: acquiring the numerical value of personnel in the factory workshop in the personnel distribution information in the factory workshop;

step two: when the number of the personnel in the workshop of the factory is more than 1, performing the fourth step; if the number of the personnel in the factory workshop is less than 1, performing the third step;

step three: judging that the factory workshop is in an unmanned mode at the moment, and generating an unmanned signal;

step four: judging that the factory workshop is in a manned mode at the moment, generating manned signals, and respectively transmitting the manned signals and the unmanned signals to the control module and the circuit planning module through the communication module;

the line planning module is used for planning an emergency escape line; the control module is used for controlling emergency lighting lamps in a factory workshop;

after receiving the person signal, the line planning module establishes data connection with the signal acquisition module through the communication module to acquire positioning data in the signal acquisition module, and substitutes the positioning data into the electronic map model to acquire a staff distribution area value;

marking the factory workshop with the employee distribution area value larger than K45 as a rejection emergency line;

marking the factory workshop with the employee distribution area value larger than K20 and the employee distribution area value smaller than K45 as a transit emergency line;

marking the factory workshop with the employee distribution area value less than K20 as a preferred emergency line;

k45 and K20 are preset values;

indoor road networks among factory workshops of the preferred emergency lines are connected together to form a preferred emergency escape road network, and the preferred emergency escape road network is connected with emergency channels;

the factory workshop mark that the emergent circuit of transfer corresponds is i, carries out emergent circuit classification of transfer through acquireing the interior hazardous articles quantity of factory workshop, specifically is:

b1: acquiring the quantity of dangerous goods in an electronic map model of the plant workshop corresponding to the transfer emergency line, and marking the quantity of the dangerous goods as Xi, wherein Xi is 1, 2, 3 … … n, and Xi represents the quantity of the dangerous goods in the plant workshop corresponding to the transfer emergency line;

b2: when Xi is larger than 15, marking the corresponding transfer emergency line as an independent transfer emergency line;

b3: when Xi is less than or equal to 15, the corresponding transit emergency line mark is unchanged;

the independent transfer emergency lines cannot be connected with each other, and can only be connected with a preferred emergency escape road network independently;

the transfer emergency lines are connected with each other to form a transfer emergency escape road network and are connected with the preferred emergency escape road network;

the elimination emergency lines can only be independently connected with a preferred emergency escape road network;

the emergency escape line network is formed by the rejected emergency lines, the transfer emergency escape road network, the independent transfer emergency lines and the optimized emergency escape road network, and is sent to the control module through the communication module;

the emergency escape line network is formed by eliminating emergency lines, transferring emergency escape road networks, independently transferring emergency lines and preferably selecting emergency escape road networks, and the emergency escape line network is sent to the control module through the communication module

The staff distribution area value is specifically to mark positioning data in the electronic map model, and accumulate the numerical values of the marked positioning data to finally obtain the staff distribution area value;

the specific construction method of the electronic map model comprises the following steps:

p1: obtaining building elements; the building elements comprise building structures, building spaces, building parts, fire-fighting facilities, dangerous goods and indoor road networks, each building element comprises a set number of types, and when an electronic map model is established, at least more than one type or more than two types need to be selected from each building element;

p2: obtaining construction CAD drawing data of a factory workshop, and converting the construction drawing data into vector map data;

p3: map symbol configuration is carried out on map elements in the electronic map model by combining vector map data, and the electronic map model is generated;

the building structure comprises a masonry structure, a frame structure, a shear wall structure, a frame shear wall structure, a barrel structure, a bent structure and a large-span structure;

the types of the building space comprise a surrounding space, a horizontal communication space, a vertical communication space and an open space;

the building component comprises a bearing part, a partition part and a communication part;

the fire-fighting facilities comprise a fire alarm system, a water fire-extinguishing system, a gas fire-extinguishing system, a fire-prevention smoke-discharging system, a fire-prevention separation system and an evacuation indication system;

dangerous goods include explosives, flammable gases, flammable liquids, flammable solids, oxidants, overoxidants, corrosives, and radioactive materials;

the indoor road network comprises center lines of corridors and passageways;

the process of converting the construction drawing data into the vector map data includes:

a1: deleting data which are not used for constructing an indoor map in the building construction drawing data;

a2: performing coordinate conversion and re-projection on the deleted construction drawing data according to the indoor map model;

a3: extracting wall lines, doors, windows, columns, pipelines and fire-fighting elements of the building from the building construction drawing data subjected to coordinate conversion and re-projection, and then generating a closed space surface according to an extraction result;

a4: configuring attribute data for wall lines, doors, windows, columns, pipelines and fire elements;

after receiving the emergency escape line network, the control module substitutes coordinate information in the emergency escape line network into the electronic map model to obtain the escape line network of the electronic map model;

acquiring illumination information on a path of the electronic map model escape line network, and adjusting the open-close state of an illumination type line in the illumination information into a closed state;

adjusting the open-close state of the illumination type line outside the path of the electronic map model escape line network to be an open-circuit state;

the control module is also used for controlling the emergency indicator lamp circuit to be opened and closed, and when the control module receives the emergency escape line network, the control module adjusts the emergency indicator lamp circuit to be in a closed state.

The invention is implemented as follows: the system comprises a signal acquisition module, a mode judgment module, a control module and a circuit planning module, wherein the signal acquisition module is used for acquiring personnel distribution information in a factory workshop, illumination information and emergency signal information in the factory workshop are acquired, when the emergency signal information is acquired, the mode judgment module starts to judge, the numerical value of personnel in the factory workshop in the personnel distribution information in the factory workshop is acquired, when the numerical value of the personnel in the factory workshop is less than 1, the factory workshop is judged to be in an unmanned mode at the moment, when the numerical value of the personnel in the factory workshop is greater than 1, the factory workshop is judged to be in the manned mode at the moment, the manned mode is respectively transmitted to the control module and the circuit planning module through the communication module, the circuit planning module is used for planning emergency escape circuits, the factory workshop with the employee distribution area value greater than K45 is marked as an emergency circuit to be eliminated, the employee distribution area value is greater than K20, the workshop with the employee distribution area value less than K45 is marked as an emergency Marking factory workshops with threshold values smaller than K20 as preferred emergency lines, distinguishing the emergency lines to obtain an emergency escape line network, and substituting coordinate information in the emergency escape line network into the electronic map model under the control of the control module to obtain the electronic map model escape line network; acquiring illumination information on a path of the electronic map model escape line network, and adjusting the open-close state of an illumination type line in the illumination information into a closed state; and adjusting the on-off state of the illumination type line outside the path of the electronic map model escape line network to be an open-circuit state, and marking a route for quick evacuation by controlling the on-off state of the line.

In the embodiments provided by the present invention, it should be understood that the disclosed apparatus, device and method can be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the modules is only one logical functional division, and there may be other divisions when the actual implementation is performed; the modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the method of the embodiment.

It will also be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference signs in the claims shall not be construed as limiting the claim concerned.

Furthermore, it is obvious that the word "comprising" does not exclude other elements or steps, and the singular does not exclude the plural. A plurality of units or means recited in the system claims may also be implemented by one unit or means in software or hardware. The terms second, etc. are used to denote names, but not any particular order.

Finally, it should be noted that the above examples are only intended to illustrate the technical process of the present invention and not to limit the same, and although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical process of the present invention without departing from the spirit and scope of the technical process of the present invention.

Claims (10)

1. An intelligent control system for emergency lighting of a factory workshop is characterized by comprising a control module, a line planning module, a mode judging module, a signal acquisition module and a communication module;

the signal acquisition module is used for acquiring personnel distribution information in a factory workshop, illumination information in the factory workshop and emergency signal information;

the emergency signal information comprises a gas concentration value, a smoke concentration value, a temperature value and a humidity value which are obtained in a factory workshop, and overproof data in the gas concentration value, the smoke concentration value, the temperature value and the humidity value are extracted and marked as abnormal data values;

when any one of the gas concentration value, the smoke concentration value, the temperature value and the humidity value generates an abnormal data value, emergency signal information is generated and transmitted into the mode judgment module through the communication module;

when the mode judging module receives the emergency signal information, the communication module acquires the personnel distribution information in the factory workshop and the illumination information in the factory workshop which are acquired in the signal acquisition module in real time, and substitutes the information into the judging model to carry out intelligent judgment, and the judging process of the mode judging module is as follows:

the method comprises the following steps: acquiring the numerical value of personnel in the factory workshop in the personnel distribution information in the factory workshop;

step two: when the number of the personnel in the workshop of the factory is more than 1, performing the fourth step; if the number of the personnel in the factory workshop is less than 1, performing the third step;

step three: judging that the factory workshop is in an unmanned mode at the moment, and generating an unmanned signal;

step four: judging that the factory workshop is in a manned mode at the moment, generating manned signals, and respectively transmitting the manned signals and the unmanned signals to the control module and the circuit planning module through the communication module;

the line planning module is used for planning an emergency escape line; the control module is used for controlling emergency lighting lamps in a factory workshop.

2. The intelligent control system for emergency lighting of factory workshops according to claim 1, wherein the line planning module establishes data connection with the signal acquisition module through the communication module after receiving a person signal, acquires positioning data in the signal acquisition module, and substitutes the positioning data into the electronic map model to obtain a staff distribution area value;

marking the factory workshop with the employee distribution area value larger than K45 as a rejection emergency line;

marking the factory workshop with the employee distribution area value larger than K20 and the employee distribution area value smaller than K45 as a transit emergency line;

marking the factory workshop with the employee distribution area value less than K20 as a preferred emergency line;

the K45 and the K20 are both preset values;

indoor road networks among factory workshops of the preferred emergency lines are connected together to form a preferred emergency escape road network, and the preferred emergency escape road network is connected with emergency channels;

the corresponding factory workshop mark of transfer emergency circuit is i, carries out the emergent circuit classification of transfer through acquireing the interior hazardous articles quantity of factory workshop, specifically is:

b1: acquiring the quantity of dangerous goods in an electronic map model of the plant workshop corresponding to the transfer emergency line, and marking the quantity of the dangerous goods as Xi, wherein Xi is 1, 2, 3 … … n, and Xi represents the quantity of the dangerous goods in the plant workshop corresponding to the transfer emergency line;

b2: when Xi is larger than 15, marking the corresponding transfer emergency line as an independent transfer emergency line;

b3: when Xi is less than or equal to 15, the corresponding transit emergency line mark is unchanged;

the independent transfer emergency lines cannot be connected with each other, and can only be connected with a preferred emergency escape road network independently;

the transfer emergency lines are connected with one another to form a transfer emergency escape road network and are connected with a preferred emergency escape road network;

the rejection emergency lines can only be connected with a preferred emergency escape road network independently;

the emergency escape line network is composed of the rejection emergency line, the transfer emergency escape road network, the independent transfer emergency line and the optimal emergency escape road network, and the emergency escape line network is sent to the control module through the communication module.

3. The intelligent factory workshop emergency lighting control system according to claim 2, wherein the staff distribution area values are obtained by marking positioning data in an electronic map model and accumulating numerical values of the marked positioning data.

4. The intelligent factory workshop emergency lighting control system according to claim 1, wherein the control module is configured to substitute coordinate information in the emergency escape route network into the electronic map model after receiving the emergency escape route network to obtain the electronic map model escape route network;

acquiring illumination information on a path of the electronic map model escape line network, and adjusting the open-close state of an illumination type line in the illumination information into a closed state;

and adjusting the open-close state of the illumination type line outside the path of the electronic map model escape line network into an open-circuit state.

5. The intelligent factory workshop emergency lighting control system according to claim 1, wherein the control module is further configured to control the emergency indicator light circuit to be turned on and off, and when the control module receives the emergency escape line network, the control module adjusts the emergency indicator light circuit to be in a closed state.

6. The intelligent control system for emergency lighting of factory workshop according to claim 4, wherein the specific construction method of the electronic map model is as follows:

p1: obtaining building elements; the building elements include building structures, building spaces, building components, fire-fighting facilities, dangerous goods, and indoor road networks, and each of the building elements includes a set number of types;

p2: acquiring building construction drawing data of a factory workshop, and converting the building construction drawing data into vector map data;

p3: and carrying out map symbol configuration on map elements in the electronic map model by combining the vector map data to generate the electronic map model.

7. The intelligent factory workshop emergency lighting control system of claim 6, wherein the building structures comprise masonry structures, frame structures, shear wall structures, frame shear wall structures, barrel structures, bent structures and large span structures;

the types of the building spaces comprise a surrounding space, a horizontal communication space, a vertical communication space and an open space;

the building component comprises a bearing part, a partition part and a communication part;

the fire-fighting facilities comprise a fire alarm system, a water fire-extinguishing system, a gas fire-extinguishing system, a fire-prevention smoke-discharging system, a fire-prevention separation system and an evacuation indication system;

the dangerous goods comprise explosives, flammable gas, flammable liquid, flammable solid, oxidant, over-oxidant, corrosive and radioactive goods;

the indoor road network comprises center lines of corridors and passageways.

8. The intelligent factory workshop emergency lighting control system of claim 6, wherein the process of converting building construction drawing data into vector map data comprises:

a1: deleting data which are not used for constructing an indoor map in the building construction drawing data;

a2: performing coordinate conversion and re-projection on the deleted building construction drawing data according to the indoor map model;

a3: extracting wall lines, doors, windows, columns, pipelines and fire-fighting elements of the building from the building construction drawing data subjected to coordinate conversion and re-projection, and then generating a closed space surface according to an extraction result;

a4: configuring attribute data for the wall lines, doors, windows, columns, pipelines, and fire elements.

9. The intelligent control system for emergency lighting in factory workshops according to claim 1, wherein the collecting of the personnel distribution information in the factory workshops is specifically that the personnel in the factory workshops need to wear a locator when entering the factory, a locating signal receiver is installed in the factory workshops, the locating signal receiver is used for receiving locating data transmitted by the locator in real time, and the number of the locators is at most the number of the personnel in the factory workshops.

10. The intelligent factory workshop emergency lighting control system according to claim 1, wherein the collection of the illumination information in the workshop is specifically achieved by acquiring real-time circuit system data in the workshop, wherein the real-time circuit system data in the workshop comprises the number of circuit lines in the workshop, the types of the circuits in the workshop and the on-off states of different types of circuits in the workshop, and by acquiring the lines with the types of the circuits in the workshop as illumination types and the on-off states of the illumination type lines, the collection of the illumination information in the workshop is achieved.

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