CN112689367A

CN112689367A - Flash system who possesses dangerous monitoring function miner's lamp in ore deposit

Info

Publication number: CN112689367A
Application number: CN202110076491.8A
Authority: CN
Inventors: 钱小英; 钱四英
Original assignee: Shenzhen Qiangliuming Photoelectric Co ltd
Current assignee: Shenzhen Qiangliuming Photoelectric Co ltd
Priority date: 2021-01-20
Filing date: 2021-01-20
Publication date: 2021-04-20
Anticipated expiration: 2041-01-20
Also published as: CN112689367B

Abstract

The invention discloses a flashing system of a mine lamp with an in-mine danger monitoring function, which comprises an in-mine danger monitoring system and the mine lamp, wherein the top of the mine lamp is fixedly connected with a mounting seat, the bottom of the mine lamp is fixedly connected with a protective cover, one side of the mine lamp is fixedly connected with a connecting wire, one side of the connecting wire, which is far away from the mine lamp, is fixedly connected with a control box, the top and the bottom of the control box are both fixedly connected with mounting blocks, the surface of the mine lamp is provided with four fixing bolts, and the protective cover is fixedly connected with the mine lamp through the fixing bolts. The mine lamp aims to solve the problems that the existing mine lamp for mining exploitation only has the function of illumination, cannot achieve the function of conversion warning under emergency, and the existing mine danger monitoring system is poor in integrity of devices for measuring displacement, stress and the like, lacks of centralized control, also brings about decentralized management, lacks of joint defense dispatching control and the like.

Description

Flash system who possesses dangerous monitoring function miner's lamp in ore deposit

Technical Field

The invention relates to the field of mining, in particular to a flickering system of a mine lamp with an in-mine danger monitoring function.

Background

Mineral products, which are generally all natural minerals or rock resources buried underground or distributed on the earth surface, or weathered rocks or deposited rocks, can be utilized by human beings, can be classified into metal, nonmetal, combustible organic and the like, and are non-renewable resources, mining is the technology and science for mining mineral resources from the earth crust and the earth surface, and mining in a broad sense also comprises mining of coal and oil, the mining industry is an important raw material industry, metal ores are main raw materials of the smelting industry, and nonmetal ores are important chemical raw materials and building materials.

At present, common underground mining engineering in a strong ground stress field can directly affect the safety of personnel and equipment in a mining area particularly when the surrounding rock pressure of a goaf, particularly the roof pressure, changes, when mining mineral products, a miner's lamp is needed, the miner's lamp is a short name for mining lamps or industrial and mining lamps, and is a general name of special lighting lamps used in mines, because of the particularity of mining operation, certain danger exists during mining, and the existing mining lamp for mining exploitation only has the function of illumination and cannot achieve the function of switching and warning under the emergency condition, and the existing mine danger monitoring system has the problems of poor integrity of devices for measuring displacement, stress and the like independently, lack of centralized control, dispersion management brought by the lack of joint defense scheduling control and the like, therefore, a flashing system of a mine lamp with an in-mine danger monitoring function is needed to meet the requirements of users.

Disclosure of Invention

The invention mainly aims to provide a flickering system of a mine lamp with an in-mine danger monitoring function, and aims to solve the problems that the existing mine lamp for mineral exploitation only has the function of illumination and cannot achieve the function of conversion warning under emergency, and the existing in-mine danger monitoring system is poor in integrity of devices for measuring displacement, stress and the like independently, lacks of centralized control, also brings about decentralized management, lacks of joint defense scheduling control and the like.

In order to achieve the purpose, the flickering system of the mine lamp with the in-mine danger monitoring function comprises the in-mine danger monitoring system and the mine lamp, wherein the top of the mine lamp is fixedly connected with a mounting base, the bottom of the mine lamp is fixedly connected with a protective cover, one side of the mine lamp is fixedly connected with a connecting wire, one side of the connecting wire, which is far away from the mine lamp, is fixedly connected with a control box, the top and the bottom of the control box are both fixedly connected with mounting blocks, four fixing bolts are arranged on the surface of the mine lamp, the protective cover is fixedly connected with the mine lamp through the fixing bolts, the in-mine danger monitoring system comprises an above mine part and an below mine part, the above mine part and the below mine part are matched for use, and the input end of the in;

the mine comprises an operation terminal, a display terminal and a server, wherein the output end of the operation terminal is unidirectionally and electrically connected with the input end of the display terminal, and the input end of the operation terminal is unidirectionally and electrically connected with the output end of the server;

the mine underground intelligent monitoring system comprises a control terminal, a monitoring module, a feedback module, a prediction early warning module, an air monitoring module, a GPS module, a switching module, a lighting mode and a flicker warning mode, wherein the output end of the monitoring module is connected with the input end of the feedback module in a one-way electric mode, the output ends of the feedback module and the GPS module are both connected with the input end of the control terminal in a one-way electric mode, the output end of the control terminal is respectively connected with the warning module and the input end of a miner lamp in a one-way electric mode, the output end of the control terminal is connected with the input end of the prediction early warning module in a two-way electric mode, the output end of the miner lamp is connected with the input end of the switching module in a one-.

Preferably, the prediction and early warning module comprises an input module, a comparison module, a storage module and an output module, the input module, the comparison module, the storage module and the output module are all connected through a wired network, the comparison module performs comparison processing and judgment on input information through computer programming, the judgment basis is matched with a big data database, and the big data database is situation data of different mining areas under different mining conditions for years and is used for matching and guiding the safe mining of a working face.

Preferably, the monitoring module comprises a first wireless transmitter, a pressure sensor, an upright column shrinkage detector, a stress sensor, a gas detector and a rock stratum detector, the pressure sensor, the upright column shrinkage detector, the stress sensor, the gas detector and the rock stratum detector feed detected data back to the control terminal through the first wireless transmitter and the feedback module, and the first wireless transmitter, the pressure sensor, the upright column shrinkage detector, the stress sensor, the gas detector and the rock stratum detector are all installed under a mine.

Preferably, the aerial monitoring module is unmanned aerial vehicle, the aerial monitoring module includes second wireless transmitter, air sensor, temperature sensor, humidity transducer, wind speed detector, surveillance camera and portrait collector, second wireless transmitter, air sensor, temperature sensor, humidity transducer, wind speed detector, surveillance camera and portrait collector all feed back the data that detect to control terminal through second wireless transmitter and GPS module, second wireless transmitter, air sensor, temperature sensor, humidity transducer, wind speed detector, surveillance camera and portrait collector all install on unmanned aerial vehicle, operation terminal can control aerial monitoring module.

Preferably, the output end of the mine is electrically connected with a wireless communication module in a bidirectional mode, the output end of the wireless communication module is electrically connected with the input end of the mine in a bidirectional mode, and signal transmission is carried out between the mine and the mine through the wireless communication module.

Preferably, the one-way electric connection of control terminal's output has warning module, warning module is bee calling organ, and bee calling organ installs in the surface of miner's lamp.

Preferably, the output end of the operation terminal is electrically connected with a wireless transmission module in a unidirectional manner, the output end of the wireless transmission module is electrically connected with a mobile terminal in a unidirectional manner, and the mobile terminal is an intelligent mobile device.

Preferably, stress sensor's quantity is a plurality of, stress sensor is used for monitoring the change of collecting space area country rock stress, the rock stratum detector is laser sensor and acoustic emission sensor, and laser sensor and acoustic emission sensor's quantity is a plurality of, and laser sensor is used for monitoring the convergence condition of collecting space area country rock, and acoustic emission sensor is used for carrying out early warning monitoring to the collecting space area country rock destruction condition.

Preferably, the portrait acquisition unit is used for acquiring a portrait, the acquired portrait is subjected to color, contrast and saturation processing through the processor, the processed data is transmitted to the server through the GPS module and the control terminal, and the operation terminal can manage and check portrait information through the server.

In the technical scheme of the invention, a user stores a big data database in a prediction early warning module in advance, the big data database stores situation data under different mining conditions of different mining areas for years to match and guide safe mining of a working face, a monitoring module and an air monitoring module respectively transmit detected related information in a mine to a control terminal through a feedback module and a GPS module, the control terminal transmits the received data to the prediction early warning module to be compared with the big data stored in advance, when the data comparison is abnormal, the control terminal controls the mine lamp to be converted, the mine lamp is switched into a flashing warning module through a switching module to warn, the control terminal controls the warning module to warn an operator to evacuate in time so as to prevent potential safety hazards, and related data under the mine are transmitted to the mine through a wireless communication module, the server is used for receiving data, and the data that the server received can be passed through operation terminal and can be carried out the transmission to display terminal and show, conveniently look over, and relevant data accessible operation terminal sends to wireless transmission module, transmit to mobile terminal through wireless transmission module, the person of being convenient for use looks over relevant information at any time, convenient use, the miner's lamp of having solved current mineral exploitation adoption only possesses the function of illumination, can't reach the function of converting the warning under taking place the emergency condition, and the solitary measurement displacement of dangerous monitoring system in current ore deposit, the wholeness of equipment such as stress is poor, lack centralized control, the dispersion management that also brings, lack a great deal of problems such as joint defense dispatch control.

Drawings

In order to more clearly illustrate the embodiments of 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 present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a diagram of an in-mine hazard monitoring system according to an embodiment of the present invention;

FIG. 2 is a block diagram of a predictive warning module according to an embodiment of the present invention;

FIG. 3 is a diagram of a monitoring module according to an embodiment of the present invention;

FIG. 4 is a block diagram of an aerial surveillance module according to an embodiment of the present invention;

FIG. 5 is a schematic view of the connection between the miner's lamp and the control box according to the embodiment of the invention;

fig. 6 is a schematic view of a miner's lamp according to an embodiment of the invention.

The reference numbers illustrate: 1. an in-mine hazard monitoring system; 2. a power supply module; 3. an operation terminal; 4. a wireless transmission module; 5. a mobile terminal; 6. a wireless communication module; 7. a switching module; 8. a flashing warning mode; 9. a miner's lamp; 10. a GPS module; 11. an aerial surveillance module; 12. a prediction early warning module; 13. a control terminal; 14. a warning module; 15. a monitoring module; 16. a feedback module; 17. mining; 18. an illumination mode; 19. a server; 20. on the mine; 21. a display terminal; 22. an input module; 23. a comparison module; 24. a storage module; 25. an output module; 26. a first wireless transmitter; 27. a formation tester; 28. a gas detector; 29. a stress sensor; 30. a column lower shrinkage detector; 31. a pressure sensor; 32. a second wireless transmitter; 33. a portrait acquisition device; 34. a surveillance camera; 35. a wind speed detector; 36. a humidity sensor; 37. a temperature sensor; 38. an air sensor; 39. a mounting seat; 40. a connecting wire; 41. mounting blocks; 42. a control box; 43. a protective cover; 44. and (5) fixing the bolt.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

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 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.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are 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 the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

Moreover, the technical solutions in the embodiments of the present invention may be combined with each other, but it is necessary to be able to be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent, and is not within the protection scope of the present invention.

The invention provides a flickering system of a mine lamp with an in-mine danger monitoring function, which solves the problems that the existing mine lamp for mineral exploitation only has an illuminating function and cannot achieve the function of converting and warning under emergency, and the existing in-mine danger monitoring system is poor in integrity of devices for measuring displacement, stress and the like, lack of centralized control, bring about decentralized management, lack of joint defense scheduling control and the like.

As shown in fig. 1 to 6, the mine lamp flickering system with the in-mine danger monitoring function according to the embodiment of the present invention includes an in-mine danger monitoring system 1 and a mine lamp 9, a mounting base 39 is fixedly connected to the top of the mine lamp 9, a protective cover 43 is fixedly connected to the bottom of the mine lamp 9, a connection line 40 is fixedly connected to one side of the mine lamp 9, a control box 42 is fixedly connected to one side of the connection line 40 away from the mine lamp 9, mounting blocks 41 are fixedly connected to both the top and the bottom of the control box 42, four fixing bolts 44 are arranged on the surface of the mine lamp 9, the protective cover 43 is fixedly connected to the mine lamp 9 through the fixing bolts 44, the in-mine danger monitoring system 1 includes an above mine 20 and an below mine 17, the above mine 20 is used in cooperation with the below mine 17, and an input end of;

the mine 20 comprises an operation terminal 3, a display terminal 21 and a server 19, wherein the output end of the operation terminal 3 is unidirectionally and electrically connected with the input end of the display terminal 21, and the input end of the operation terminal 3 is unidirectionally and electrically connected with the output end of the server 19;

the underground mine 17 comprises a control terminal 13, a monitoring module 15, a feedback module 16, a prediction early warning module 12, an aerial monitoring module 11, a GPS module 10, a switching module 7, an illumination mode 18 and a flicker warning mode 8, wherein the output end of the monitoring module 15 is in one-way electric connection with the input end of the feedback module 16, the output ends of the feedback module 16 and the GPS module 10 are both in one-way electric connection with the input end of the control terminal 13, the output end of the control terminal 13 is respectively in one-way electric connection with the input ends of the warning module 14 and the miner lamp 9, the output end of the control terminal 13 is in two-way electric connection with the input end of the prediction early warning module 12, the output end of the miner lamp 9 is in one-way electric connection with the input end of the switching module 7, and the output end of.

In the technical scheme of the invention, a user stores a big data database in a prediction early warning module 12 in advance, the big data database is situation data under different mining conditions of different mining areas for years and is used for matching and guiding safe mining of a working face, a monitoring module 15 and an air monitoring module 11 respectively transmit detected relevant information in a mine to a control terminal 13 through a feedback module 16 and a GPS module 10, the control terminal 13 transmits the received data to the prediction early warning module 12 to be compared with the big data stored in advance, when the data comparison is abnormal, the control terminal 13 controls a mine lamp 9 to convert, the mine lamp 9 is switched into a flicker warning module 14 to warn through a switching module 7, the control terminal 13 controls the warning module 14 to warn operators to evacuate in time so as to prevent potential safety hazards, and relevant data under the mine 17 is transmitted to a mine 20 through a wireless communication module 6, server 19 is used for the received data, and the data that server 19 received can be passed through operation terminal 3 and can be transmitted to display terminal 21 and show, conveniently look over, and relevant data accessible operation terminal 3 sends to wireless transmission module 4, transmit to mobile terminal 5 through wireless transmission module 4, the person of facilitating the use looks over relevant information at any time, convenient use, the miner's lamp of having solved current mineral exploitation and adopting only possesses the function of illumination, can't reach the function of converting the warning under taking place the emergency condition, and current dangerous monitoring system solitary measurement displacement in the ore deposit, the wholeness of equipment such as stress is poor, lack centralized control, the decentralized management that also brings, lack many problems such as joint defense dispatch control.

Referring to fig. 2, the prediction and early warning module 12 includes an input module 22, a comparison module 23, a storage module 24, and an output module 25, the input module 22, the comparison module 23, the storage module 24, and the output module 25 are all connected via a wired network, the comparison module 23 performs comparison processing and judgment on the input information through computer programming, and the judgment basis is matched with a big data database, and the big data database is situation data of different mining areas under different mining conditions for years, so as to match and guide the safe mining of the working face. In the embodiment, before the mining of the working face, a user collects the columnar data of all ground boreholes along the trend of the working face, inputs the basic information of the fully-columnar rock stratum of the boreholes from the main mining coal bed to the ground surface, the physical and mechanical parameters, the mining height of the coal bed and the situation data under different mining conditions of different mining areas for years into the input module 22 and the storage module 24 of the prediction and early warning module 12, carries out the position judgment of the key layer on the columnar boreholes on the ground by the comparison module 23, and according to the judgment result of the position of the key layer, and by combining the mining height of the coal bed, the occurrence properties of the direct roof and each key layer, the distance position relation between each key layer and the main mining coal bed, the erosion degree of the key layer in the topographic features of the valley, the distance and the position corresponding relation between the left coal pillar of the upper coal layer and the working face of the lower coal layer, judges and determines that each key layer of the overlying rock presents the breaking form of a cantilever beam or a masonry beam, the overlying rock, therefore, the initial pressure and the periodic pressure of the working face are predicted before the working face is mined, the pressure prediction before the working face is automatically realized, and meanwhile, the reasonable type selection of the working face support under the specific geological mining condition is given for matching and guiding the safe mining of the working face.

Further, with continued reference to fig. 3, the monitoring module 15 includes a first wireless transmitter 26, a pressure sensor 31, an upright shrinkage detector 30, a stress sensor 29, a gas detector 28 and a rock formation detector 27, the pressure sensor 31, the upright shrinkage detector 30, the stress sensor 29, the gas detector 28 and the rock formation detector 27 feed back detected data to the control terminal 13 through the first wireless transmitter 26 and the feedback module 16, and the first wireless transmitter 26, the pressure sensor 31, the upright shrinkage detector 30, the stress sensor 29, the gas detector 28 and the rock formation detector 27 are all installed under the mine 17. In this embodiment, through the first wireless transmitter 26, the first wireless transmitter 26 is used for transmitting the information monitored by the monitoring module 15, and the pressure sensor 31 is used for monitoring the pressure in the mine, the column shrinkage detector 30 is used for monitoring the working resistance of the hydraulic support and the column shrinkage of the hydraulic support, the stress sensor 29 is used for monitoring the stress change of the surrounding rock of the goaf, the gas detector 28 is used for monitoring the gas content in the mine, and the rock formation detector 27 is used for monitoring the convergence condition of the surrounding rock of the goaf and carrying out early warning monitoring on the damage condition of the surrounding rock of the goaf.

With reference to fig. 4, the aerial surveillance module 11 is an unmanned aerial vehicle, the aerial surveillance module 11 includes a second wireless transmitter 32, an air sensor 38, a temperature sensor 37, a humidity sensor 36, a wind speed detector 35, a surveillance camera 34 and a portrait collector 33, the second wireless transmitter 32, the air sensor 38, the temperature sensor 37, the humidity sensor 36, the wind speed detector 35, the surveillance camera 34 and the portrait collector 33 all feed detected data back to the control terminal 13 through the second wireless transmitter 32 and the GPS module 10, the second wireless transmitter 32, the air sensor 38, the temperature sensor 37, the humidity sensor 36, the wind speed detector 35, the surveillance camera 34 and the portrait collector 33 are all installed on the unmanned aerial vehicle, and the operation terminal 3 can operate the aerial surveillance module 11. In this embodiment, through aerial surveillance module 11, can patrol and carry out real time monitoring to air, temperature, humidity and the wind speed in the ore to prevent that the security of mining in the ore is influenced to the abnormal conditions, through surveillance camera head 34 and portrait collector 33, can carry out the control to mining conditions in the ore and mining personnel in the ore, increased the security of mining in the ore.

Referring to fig. 1, an output end of the mine 20 is electrically connected to the wireless communication module 6 in a bidirectional manner, an output end of the wireless communication module 6 is electrically connected to an input end of the mine 17 in a bidirectional manner, and signal transmission is performed between the mine 20 and the mine 17 through the wireless communication module 6. In this embodiment, the wireless communication module 6 can implement information intercommunication between the mine 20 and the mine 17, the related information detected by the mine 17 can be transmitted to the mine 20 through the wireless communication module 6 for display and viewing, and the related instruction of the mine 20 can be transmitted to the mine 17 through the wireless communication module 6 for implementation.

In addition, referring to fig. 1, the output end of the control terminal 13 is electrically connected to a warning module 14 in a single direction, the warning module 14 is a buzzer, and the buzzer is mounted on the surface of the miner's lamp 9. In this embodiment, through the warning module 14, when an emergency situation occurs in the mine 17, the control terminal 13 controls the warning module 14 to operate, the buzzer buzzes, and prompts mining personnel in the mine 17 to evacuate in time, so that accidents are reduced.

Referring to fig. 1, the output end of the operation terminal 3 is electrically connected to the wireless transmission module 4 in a unidirectional manner, the output end of the wireless transmission module 4 is electrically connected to the mobile terminal 5 in a unidirectional manner, and the mobile terminal 5 is an intelligent mobile device. In this embodiment, through wireless transmission module 4, can transmit the relevant information of 17 under the ore deposit, and information transmits to mobile terminal 5 through wireless transmission module 4, through mobile terminal 5, has made things convenient for the user to look over the relevant information of 17 under the ore deposit at any time, when the accident takes place, has also made things convenient for user's timely processing.

Referring to fig. 3, the number of the stress sensors 29 is several, the stress sensors 29 are used for monitoring the stress change of the goaf surrounding rock, the rock formation detector 27 is a laser sensor and an acoustic emission sensor, the number of the laser sensors and the acoustic emission sensor is several, the laser sensors are used for monitoring the convergence condition of the goaf surrounding rock, and the acoustic emission sensor is used for performing early warning monitoring on the damage condition of the goaf surrounding rock. In this embodiment, through a plurality of stress sensor 29 and rock stratum detector 27, and stress sensor 29 and rock stratum detector 27 even distribution have made things convenient for diversified goaf and the rock stratum condition to survey 17 under the ore to avoid the emergence of unexpected hidden danger.

In addition, referring to fig. 4, the portrait acquisition unit 33 is configured to acquire a portrait, perform color, contrast, and saturation processing on the acquired portrait through the processor, and transmit the processed data to the server 19 through the GPS module 10 and the control terminal 13, and the operation terminal 3 may manage and view portrait information through the server 19. In this embodiment, the image collector 33 can collect images of mining personnel under the mine 17, so that the confirmation of each personnel and station under the mine 17 is facilitated, and the safe operation of mining operation of the mine 17 is ensured.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a scintillation system that possesses dangerous monitoring function miner's lamp in ore deposit which characterized in that, the scintillation system that possesses dangerous monitoring function miner's lamp in ore deposit includes dangerous monitoring system (1) in ore deposit and miner's lamp (9), the top fixedly connected with mount pad (39) of miner's lamp (9), the bottom fixedly connected with protection casing (43) of miner's lamp (9), one side fixedly connected with connecting wire (40) of miner's lamp (9), one side fixedly connected with control box (42) that connecting wire (40) kept away from miner's lamp (9), the top and the bottom of control box (42) all fixedly connected with installation piece (41), the surface of miner's lamp (9) is provided with four fixing bolt (44), protection casing (43) are through fixing bolt (44) and miner's lamp (9) fixed connection, dangerous monitoring system (1) in ore deposit includes aboveground (20) and undersround (17), the mine upper part (20) and the mine lower part (17) are matched for use, and the input end of the mine inner danger monitoring system (1) is unidirectionally and electrically connected with a power supply module (2);

the mine (20) comprises an operation terminal (3), a display terminal (21) and a server (19), wherein the output end of the operation terminal (3) is unidirectionally and electrically connected with the input end of the display terminal (21), and the input end of the operation terminal (3) is unidirectionally and electrically connected with the output end of the server (19);

the mine underground (17) comprises a control terminal (13), a monitoring module (15), a feedback module (16), a prediction early warning module (12), an air monitoring module (11), a GPS module (10), a switching module (7), an illumination mode (18) and a flicker warning mode (8), wherein the output end of the monitoring module (15) is unidirectionally and electrically connected with the input end of the feedback module (16), the output ends of the feedback module (16) and the GPS module (10) are unidirectionally and electrically connected with the input end of the control terminal (13), the output end of the control terminal (13) is unidirectionally and electrically connected with the input ends of a warning module (14) and a mine lamp (9), the output end of the control terminal (13) is bidirectionally and electrically connected with the input end of the prediction early warning module (12), and the output end of the mine lamp (9) is unidirectionally and electrically connected with the input end of the switching module (7), the output end of the switching module (7) is respectively and unidirectionally electrically connected with the input ends of the illumination mode (18) and the flicker warning mode (8).

2. The mining lamp flickering system with the in-mine danger monitoring function according to claim 1, wherein the prediction and early warning module (12) comprises an input module (22), a comparison module (23), a storage module (24) and an output module (25), the input module (22), the comparison module (23), the storage module (24) and the output module (25) are all connected through a wired network, the comparison module (23) performs comparison processing and judgment on input information through computer programming, the judgment is based on matching with a big data database, and the big data database is situation data of different mining areas under different mining conditions for years, so as to match and guide safe mining of a working face.

3. The mining lamp flickering system with an in-mine danger monitoring function according to claim 1, the monitoring module (15) comprises a first wireless transmitter (26), a pressure sensor (31), an upright column shrinkage detector (30), a stress sensor (29), a gas detector (28) and a rock stratum detector (27), the pressure sensor (31), the column shrinkage detector (30), the stress sensor (29), the gas detector (28) and the rock stratum detector (27) feed detected data back to the control terminal (13) through the first wireless transmitter (26) and the feedback module (16), the first wireless transmitter (26), the pressure sensor (31), the column shrinkage detector (30), the stress sensor (29), the gas detector (28) and the rock stratum detector (27) are all installed under a mine (17).

4. The mining lamp flashing system with the mine hazard monitoring function according to claim 1, wherein the aerial monitoring module (11) is an unmanned aerial vehicle, the aerial monitoring module (11) comprises a second wireless transmitter (32), an air sensor (38), a temperature sensor (37), a humidity sensor (36), a wind speed detector (35), a monitoring camera (34) and a portrait acquisition unit (33), the second wireless transmitter (32), the air sensor (38), the temperature sensor (37), the humidity sensor (36), the wind speed detector (35), the monitoring camera (34) and the portrait acquisition unit (33) feed detected data back to the control terminal (13) through the second wireless transmitter (32) and the GPS module (10), and the second wireless transmitter (32), the air sensor (38), the temperature sensor (37) and the portrait acquisition unit (33) feed detected data back to the control terminal (13), Humidity transducer (36), wind speed detector (35), surveillance camera head (34) and people image collector (33) all install on unmanned aerial vehicle, aerial surveillance module (11) can be controlled in operation terminal (3).

5. The system according to claim 1, wherein the output end of the mine head (20) is electrically connected with the wireless communication module (6) in two directions, the output end of the wireless communication module (6) is electrically connected with the input end of the mine bottom (17) in two directions, and the signal transmission between the mine head (20) and the mine bottom (17) is performed through the wireless communication module (6).

6. The mining lamp flickering system with the in-mine danger monitoring function according to claim 1, wherein an output end of the control terminal (13) is electrically connected with a warning module (14) in a single direction, the warning module (14) is a buzzer, and the buzzer is mounted on the surface of the mining lamp (9).

7. The mining lamp flickering system with the in-mine danger monitoring function according to claim 1, wherein an output end of the operation terminal (3) is electrically connected with a wireless transmission module (4) in a unidirectional manner, an output end of the wireless transmission module (4) is electrically connected with a mobile terminal (5) in a unidirectional manner, and the mobile terminal (5) is an intelligent mobile device.

8. The mining lamp flickering system with the in-mine danger monitoring function according to claim 3, wherein the number of the stress sensors (29) is several, the stress sensors (29) are used for monitoring stress changes of surrounding rocks of the goaf, the rock formation detector (27) is a laser sensor and an acoustic emission sensor, the number of the laser sensor and the acoustic emission sensor is several, the laser sensor is used for monitoring convergence of the surrounding rocks of the goaf, and the acoustic emission sensor is used for early warning and monitoring damage of the surrounding rocks of the goaf.

9. The mining lamp flickering system with the in-mine danger monitoring function according to claim 4, wherein the portrait collector (33) is used for collecting the portrait, the collected portrait is processed by a processor in color, contrast and saturation, the processed portrait is transmitted to the server (19) through the GPS module (10) and the control terminal (13), and the operation terminal (3) can manage and view portrait information through the server (19).