CN107369121A

CN107369121A - A kind of real time data analogy method of coal mine information system

Info

Publication number: CN107369121A
Application number: CN201710605420.6A
Authority: CN
Inventors: 侯涛; 张昊; 杨会龙; 田敬秋; 孙涛; 王景阳
Original assignee: CHINA COAL ELECTRIC Co Ltd
Current assignee: CHINA COAL ELECTRIC Co Ltd
Priority date: 2017-07-24
Filing date: 2017-07-24
Publication date: 2017-11-21
Anticipated expiration: 2037-07-24
Also published as: CN107369121B

Abstract

The present invention discloses a kind of real time data analogy method of coal mine information system, including：The Back ground Information of safety monitoring system and the essential information of personnel location system of composition coal mine information system are obtained respectively；According to the real time data of the Back ground Information and service logic, at set time intervals dynamic analog safety monitoring system of safety monitoring system, and by its in real time the real time data text of deposit safety monitoring system；According to the real time data of the essential information and service logic, at set time intervals dynamic analog personnel location system of personnel location system, and by its in real time the real time data text of deposit personnel location system.The quick exploitation of the achievable coal mine information system project of the present invention, has not only saved project development cost and has also saved the project development time.

Description

Real-time data simulation method of coal mine information system

Technical Field

The invention relates to the technical field of computers. And more particularly, to a real-time data simulation method for a coal mine informatization system.

Background

In the process of developing a coal mine information system project of a coal mine enterprise, the work of integrating real-time data of two systems, namely an existing safety monitoring system and a personnel positioning system of a mine often occurs, and the data acquisition modes of the safety monitoring system and the personnel positioning system are roughly two types: the first is to collect the real-time text generated by the client of the manufacturer; the second method is to directly read the database of the manufacturer or call the real-time data interface provided by the manufacturer to read. From the perspective of safety and stability, the first data acquisition mode is more reasonable, because the real-time text generated by a manufacturer client is directly read, the interactive coupling with the safety monitoring system and the personnel positioning system can not be directly realized, the safety monitoring system and the personnel positioning system which are in production and operation are not influenced, the secondary development work of communication with the manufacturer is not needed, the generation and acquisition of the real-time data are relatively independent, and the requirement of the system stability is met.

When coal mine information system project development of coal mine enterprises is carried out, system functions of a monitoring management system are tested in an early stage generally through interaction between a monitoring object of a simulation data center and the monitoring management system.

Because the real-time data text can only be obtained on the coal mine site, the development difficulty of coal mine information system projects is increased, if the real-time data text does not exist, the projects can only be developed on the site, and the period and the cost of project development are undoubtedly increased. And after the project is finished, a project demonstration environment is often left, the real-time data display also depends on the real-time data text, and if no dynamic real-time text exists, the data of the project demonstration is static.

Therefore, according to actual needs, a real-time data simulation method of the coal mine information system, which can perform project development, early-stage testing and project demonstration on the coal mine information system of a coal mine enterprise according to the real-time text information standard format of the safety monitoring system and the personnel positioning system and is not dependent on the real-time data text obtained on the coal mine site, and can be applied to most domestic coal mines, is needed.

Disclosure of Invention

The invention aims to provide a real-time data simulation method of a coal mine information system, which aims to realize the coal mine information system project development without the need of a coal mine site, remotely perform project development, early-stage test and project demonstration close to actual production, and then directly deploy and develop the coal mine information system project completed in the coal mine site.

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

a real-time data simulation method of a coal mine information system comprises the following steps:

respectively acquiring basic information of a safety monitoring system and basic information of a personnel positioning system which form a coal mine information system;

dynamically simulating real-time data of the safety monitoring system according to the basic information and the service logic of the safety monitoring system and a set time interval, and storing the real-time data of the safety monitoring system into a real-time data text of the safety monitoring system in real time;

and dynamically simulating the real-time data of the personnel positioning system according to the basic information and the service logic of the personnel positioning system and the set time interval, and storing the real-time data of the personnel positioning system into a real-time data text of the personnel positioning system in real time.

Preferably, the basic information of the safety monitoring system comprises main attributes of the measuring points of the safety monitoring system, and the main attributes of the measuring points comprise measuring point numbers, measuring point types, measuring point value ranges and upper and lower alarm limits.

Preferably, the dynamically simulating real-time data of the safety monitoring system according to the basic information and the service logic of the safety monitoring system at the set time interval further comprises: and according to the main attributes of the measuring points of the safety monitoring system and the service logic of the measurement of the measuring points, randomly simulating to generate the current measured values of the measuring points and the current states of the measuring points at set time intervals.

Preferably, the current state of the measuring point comprises normal state, alarm state, breakpoint state, reset state and adjustment state.

Preferably, the text format of the real-time data text of the security monitoring system is rtdata.

Preferably, the basic information of the personnel positioning system comprises coal mine basic information, area basic information, substation basic information and personnel basic information.

Preferably, the coal mine basic information comprises the number of a coal mine, the name of the coal mine and the upper limit of underground personnel, the area basic information comprises the area number, the area name and the upper limit of the area personnel, the substation basic information comprises the substation number, the name of the substation, the coordinates of the substation and the coordinates of track points, and the personnel basic information comprises the personnel card number, the personnel name, the personnel position and the department to which the personnel belong.

Preferably, the dynamically simulating real-time data of the people positioning system according to the set time interval according to the basic information and the business logic of the people positioning system further comprises: and randomly simulating to generate the current number of people in the underground well, the current number of people in the area and the current number of people in the substation at set time intervals according to the basic information of the coal mine, the basic information of the area, the basic information of the substation, the basic information of the personnel and the business logic of personnel positioning.

Preferably, the text format of the real-time data text of the person positioning system is ryss.

Preferably, the basic information of the safety monitoring system, the basic information of the personnel positioning system, the real-time data text of the safety monitoring system and the real-time data text of the personnel positioning system are all stored in the database.

The invention has the following beneficial effects:

the technical scheme of the invention can realize the rapid development of coal mine information system projects, thereby not only saving the project development cost, but also saving the project development time.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings;

fig. 1 shows a flow chart of a real-time data simulation method of a coal mine informatization system.

Detailed Description

In order to more clearly illustrate the invention, the invention is further described below with reference to preferred embodiments and the accompanying drawings. Similar parts in the figures are denoted by the same reference numerals. It is to be understood by persons skilled in the art that the following detailed description is illustrative and not restrictive, and is not to be taken as limiting the scope of the invention.

As shown in fig. 1, the method for simulating real-time data of a coal mine informatization system disclosed by the invention comprises the following steps:

respectively acquiring basic information of a safety monitoring system and basic information of a personnel positioning system, wherein the coal mine informatization system consists of the safety monitoring system and the personnel positioning system;

Wherein,

the set time interval can be adjusted according to actual needs.

The steps of dynamically simulating the real-time data of the safety monitoring system according to the basic information and the service logic of the safety monitoring system and storing the real-time data of the safety monitoring system into the real-time data text of the safety monitoring system in real time, and the steps of dynamically simulating the real-time data of the personnel positioning system according to the basic information and the service logic of the personnel positioning system and storing the real-time data of the personnel positioning system into the real-time data text of the personnel positioning system in real time according to the set time intervals are not sequentially executed, and can also be simultaneously executed.

The basic information of the safety monitoring system comprises the main attributes of the measuring points of the safety monitoring system, the main attributes of the measuring points comprise measuring point numbers, measuring point types, measuring point value ranges, alarm upper and lower limits and the like, and the format of the basic information text of the safety monitoring system is dev.

In specific implementation, "dynamically simulating real-time data of the safety monitoring system according to basic information and business logic of the safety monitoring system and a set time interval" further includes: and according to the main attributes of the measuring points of the safety monitoring system and the service logic of the measurement of the measuring points, randomly simulating to generate the current measured values of the measuring points and the current states of the measuring points at set time intervals. For example, if the measuring point is a temperature sensor, the business logic of measuring at the measuring point can be understood as the working mode or process of measuring at the measuring point. Further, the current state of the measuring point comprises normal state, alarming state, breakpoint state, resetting state and adjusting state.

The basic information of the personnel positioning system comprises coal mine basic information, area basic information, substation basic information and personnel basic information; further, the coal mine basic information comprises a coal mine number, a coal mine name and an underground personnel upper limit, the area basic information comprises an area number, an area name and an area personnel upper limit, the substation basic information comprises a substation number, a substation name, a substation coordinate and a track point coordinate, and the personnel basic information comprises a personnel card number, a personnel name, a personnel position and a department to which the personnel belongs.

In specific implementation, "dynamically simulating real-time data of the staff positioning system according to the basic information and the service logic of the staff positioning system and the set time interval" further includes: and randomly simulating to generate the current number of people in the underground well, the current number of people in the area and the current number of people in the substation at set time intervals according to the basic information of the coal mine, the basic information of the area, the basic information of the substation, the basic information of the personnel and the business logic of personnel positioning. The business logic of personnel positioning can be understood as the working mode or process of personnel positioning by the personnel positioning system.

The text format of the real-time data text of the safety monitoring system is rtdata.

In specific implementation, the basic information of the safety monitoring system, the basic information of the personnel positioning system, the real-time data text of the safety monitoring system and the real-time data text of the personnel positioning system are all stored in the database.

Various texts appearing in the real-time data simulation method of the coal mine information system disclosed by the invention are further described by way of examples as follows:

text content of basic information of a security monitoring system in dev.txt format is as follows:

113002,2016/11/11 7:44:47,381,,

6,4,1# Fennel gas, 1, gas,% CH4,0,4, 0.75,

16,2, gas of central substation, 1, gas,% CH4,0,4, 0.5,

17,2, central substation temperature, 1, temperature, ° c, -5,45, 34,

18,3, two panel substation gas,% CH4,0,4, 0.5,% CH4,

19,3, two-panel substation temperature, 1, temperature, ° c, -5,45, 34,

20,4,1# voacao carbon monoxide, 1, carbon monoxide, ppm,0,1000, 24,

21,4,1# wind tunnel wind speed, 1, wind speed, m/s,0,15,

22,4,2# voacao carbon monoxide, 1, carbon monoxide, ppm,0,1000, 24,

24,4,1# wind cave negative pressure, 1, negative pressure, kPa,0,5,,

25,4,2# wind tunnel negative pressure, 1, negative pressure, kPa,0,5,,

28,8, total reflux gas, 1, gas,% CH4,0,4, 0.75,

30,4,2# bellows gas, 1, gas,% CH4,0,4, 0.75,

35,8,2# cabin chamber air door switch A,2, air door, 0,1,,

44,13, gas, 1, gas,% CH4,0,4, 0.5,

45,13, carbon monoxide, ppm,0,1000, 24, concentrated in the upper bin belt conveyor head, carbon monoxide, ammonia, hydrogen, ammonia,

46,14 carbon monoxide, 1, ppm,0,1000, 24,

54,14, gas of distribution chamber at lower port of coal bunker, 1, gas,% CH4,0,4, 0.5,

55,8, total reflux temperature, 1, temperature, ° c, -5,45, 26,

69,15,3101 corner gas, 1, gas,% CH4,0,4, 0.8,% CH4,

73,13, the temperature of the distribution chamber of the upper cabin is 1, the temperature is lower than the temperature, 5 to 45 degrees, 34 degrees,

83,15,3101, working face return air flow gas, 1, gas,% CH4,0,4, 0.8,

96,8 total carbon monoxide, 1, carbon monoxide, ppm,0,1000, 24,

123,4,1# main ventilator on/off, 2, on/off, 0,1,,

124,4,2# main ventilator on/off, 2, on/off, 0,1,,

126,37,3102 auxiliary conveying lane auxiliary fan, 2, start and stop, 0,1, and 3,

… … (the ellipses here indicate that the text content of the basic information of the safety monitoring system is not shown in its entirety)

After dynamically simulating the real-time data of the safety monitoring system according to the basic information and the service logic of the safety monitoring system and the set time interval, the real-time data text content of the safety monitoring system with the rtdata and txt format, in which the real-time data of the safety monitoring system is stored, is as follows:

102004,2017-04-14 09:41:29,182,0,0,0

1003,0,0

4208,9.25,0

4302,892.06,0

2009,0,0

1004,0,0

4209,0,0

4301,5.49,0

1001,1,0

4206,168.27,0

4304,838.09,0

1002,1,0

4207,615.12,0

4303,0.11,0

4306,197.65,0

4204,2.70,0

1007,0.25,0

4305,7.88,0

4205,5.91,0

2005,5.94,0

4308,0.59,0

4202,8.68,0

1005,1,0

4307,10.59,0

… … (the ellipses here indicate that the real-time data text content of the safety monitoring system is not shown in its entirety)

In the basic information of the personnel positioning system, the content of the basic information text of the coal mine in RYKJ.txt format is as follows:

102002; a middling coal group; hole village mine; tunba, Touguese; hole village mine; the country has the country; a middling coal group; the hole is long; xuzhou city of Jiangsu province, Peizhou, Tungyuan coal electric company; 500, a step of; 500, a step of; 500, a step of; 8; 89024404, respectively; 200 of a carrier; 8; CKXKZ 001; AQSCXKZ 001; MTSCXKZ 001; kzannsczg 001; KZZGZ 001; GSZZBH 001; low gas content; 1500; 200 of a carrier; 10.35.3.208, respectively; 10.35.3.208, respectively; 10.3.35.208, respectively; 116.959846496582, respectively; 34.7814750671387, respectively;

in the basic information of the personnel positioning system, the text content of the basic information of the RYQY.

102002; a key area; 10200201, respectively; 500, a step of; i3 mining area

102002; a wellhead area; 10200202, respectively; 500, a step of; i4 mining area

102002; a key area; 10200203, respectively; 500, a step of; i5 mining area

102002; a key area; 10200204, respectively; 500, a step of; i6 mining area

102002; a key area; 10200205, respectively; 500, a step of; II1 mining area

102002; a key area; 10200206, respectively; 500, a step of; II3 mining area

102002; a key area; 10200207, respectively; 500, a step of; II5 mining area

102002; a key area; 10200208, respectively; 500, a step of; III3 mining area

102002; a key area; 10200209, respectively; 500, a step of; III4 mining area

102002; a key area; 10200210, respectively; 500, a step of; III5 mining area

102002; a key area; 10200211, respectively; 500, a step of; IV1 mining area

102002; a key area; 10200212, respectively; 500, a step of; upper port of auxiliary well

102002; a key area; 10200213, respectively; 500, a step of; auxiliary well bottom

102002; a key area; 10200214, respectively; 500, a step of; hybrid wellhead

102002; a key area; 10200216, respectively; 500, a step of; hybrid downhole well head

102002; a key area; 10200217, respectively; 500, a step of; other regions

102002; a key area; 10200218, respectively; 500, a step of; i2 mining area

In the basic information of the personnel positioning system, the text content of substation basic information in RYFZ.

102002; 1; substation distribution; 1020020101, respectively; an upper port of the auxiliary well; x; x; upper port of auxiliary well

102002; 2; substation distribution; 1020020202, respectively; a sub-well south gate; x; x; auxiliary well south door

102002; 3; substation distribution; 1020020303, respectively; 375 yard; x; x; 375 yard

102002; 4; substation distribution; 1020020404, respectively; a No. 1 belt slope changing point; x; x; no. 1 belt slope changing point

102002; 5; substation distribution; 1020020505, respectively; a dispatch station; x; x; dispatching station

102002; 6; substation distribution; 1020020606, respectively; a second station; x; x; two stations

102002; 7; substation distribution; 1020020707, respectively; II1 rear of winch house; x; x; II1 rear of winch house

102002; 8; substation distribution; 1020020808, respectively; II3 winch houses; x; x; II3 winch room

102002; 9; substation distribution; 1020020909, respectively; III3 throwing; x; x; III 3A way-throwing substation

102002; 10; substation distribution; 1020021010, respectively; IV1 up-conversion; x; x; IV1 Up-conversion

102002; 11; substation distribution; 1020021111, respectively; II5 pump house; x; x; II5 pump house

102002; 12; substation distribution; 1020021212, respectively; a Dongsanfu explosive storehouse; x; x; dongsanyao medicine storehouse

102002; 13; substation distribution; 1020021313, respectively; i6 throwing; x; x; i6 four throwing path

102002; 14; substation distribution; 1020021414, respectively; II3 yard of vehicles; x; x; II3 parking lot

102002; 15; substation distribution; 1020021616, respectively; II5 refuge chamber No. 1; x; x; II5 refuge chamber No. 1

102002; 16; substation distribution; 1020021717, respectively; i4 yard of vehicles; x; x; i4 dispatching station

102002; 17; substation distribution; 1020020118, respectively; checking and substation of the auxiliary well mouth; x; x; sub-well card checking substation

102002; 18; substation distribution; 1020021371, respectively; III3 down-shift; x; x; III3 Down-Change

102002; 19; substation distribution; 1020021472, respectively; -785 four-way gate; x; x; -785 four-way door

… … (the ellipses here indicate that the text contents of the substation basic information are not all shown)

In the basic information of the person positioning system, the text content of the basic information of the person in RYRY.txt format is as follows:

102002; 10200201064, respectively; material carts 12-111; 000000000000000000, respectively; material turning; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201065, respectively; a mine car 10-224; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201066, respectively; 14-9 of mine cars; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201067, respectively; 09-181 parts of mine car; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201068, respectively; 09-88 parts of mine car; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201069, respectively; a man driving 4; 000000000000000000, respectively; people drive a vehicle; managing vehicles in a transportation department; a whole mine; 1980-01-01; (ii) a (ii) a (ii) a (ii) a (ii) a (ii) a (ii) a (ii) a 1900-01-01

102002; 10200201070, respectively; a man car 37; 000000000000000000, respectively; people drive a vehicle; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201071, respectively; 08-139 of mine car; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201072, respectively; a mine car 12-27; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201073, respectively; a mine car 14-28; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201074, respectively; 08-231 mine cars; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

102002; 10200201075, respectively; 08-142 mine cars; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 1900-01-01; x; (ii) a x; x; x; x; x; (ii) a 1900-01-01

… … (the ellipses here indicate that the text content of the basic information of the person is not shown in its entirety)

After dynamically simulating the real-time data of the personnel positioning system according to the basic information and the service logic of the personnel positioning system and the set time interval, the real-time data text content of the personnel positioning system in the RYSS.

102002; a middling coal group; hole village mine; hole village mine; 219; 2015-06-01/21:24: 41; 1; 10200201075, respectively; 08-142 mine cars; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 2015-06-01/20:08: 00; xxxx-xx-xx/xx: xx: xx; 10200203, respectively; i5 panel; 29; 2015-06-01/20:24: 15; 1020020303, respectively; 375 yard; 29; 2015-06-01/20:24: 15; 1020020202&2015-06-01/20:08:00,1020020303&2015-06-01/20:24:15

102002; a middling coal group; hole village mine; hole village mine; 219; 2015-06-01/21:24: 41; 1; 10200201262, respectively; 14-93 mine cars; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 2015-06-01/11:35: 37; xxxx-xx-xx/xx: xx: xx; 10200211, respectively; IV1 panel; 32, a first step of removing the first layer; 2015-06-01/13:34: 19; 1020021170, respectively; i4 west yard; 16; 2015-06-01/13:34: 19; 1020020202&2015-06-01/11:35:37,1020020505&2015-06-01/13:15:23,1020020606&2015-06-01/13:18:47,1020021212&2015-06-01/13:28:23,1020021414&2015-06-01/13:29:44,1020021170&2015-06-01/13:34:19

102002; a middling coal group; hole village mine; hole village mine; 219; 2015-06-01/21:24: 41; 1; 10200201311, respectively; 14-91 of a mine car; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 2015-05-31/05:42: 17; xxxx-xx-xx/xx: xx: xx; 10200202, respectively; i4 panel; 24; 2015-06-01/20:01: 31; 1020020202, respectively; a sub-well south gate; 24; 2015-06-01/20:01: 31; 1020020202&2015-05-31/05:42:17,1020020505&2015-05-31/23:47:50,1020020606&2015-05-31/23:59:07,1020020707&2015-06-01/00:01:43,1020021212&2015-06-01/00:10:15,1020021414&2015-06-01/00:12:13,1020021170&2015-06-01/00:14:51,1020021717&2015-06-01/00:16:49,1020021430&2015-06-01/00:30:30,1020021717&2015-06-01/19:12:12,1020021170&2015-06-01/19:15:22,1020021414&2015-06-01/19:19:52,1020021212&2015-06-01/19:22:30,1020020707&2015-06-01/19:33:22,1020020606& 387-01/19: 37:13,1020020505&2015-06-01/19:42:23,1020020202: 2015-01/19: 42: 2015 &2015-06-01/20:01:31

102002; a middling coal group; hole village mine; hole village mine; 219; 2015-06-01/21:24: 41; 1; 10200201340, respectively; 08-269 of mine car; 000000000000000000, respectively; a mine car; managing vehicles in a transportation department; a whole mine; 2015-06-01/10:30: 31; xxxx-xx-xx/xx: xx: xx; 10200214, respectively; mixing the upper hole of the well; 26; 2015-06-01/16:42: 19; 1020021430, respectively; 8201 except the material channel; 15; 2015-06-01/16:42: 19; 1020020202&2015-06-01/10:30:31,1020020505&2015-06-01/11:07:29,1020020606&2015-06-01/15:32:02,1020020707&2015-06-01/15:38:09,1020021212&2015-06-01/15:49:13,1020021414&2015-06-01/15:54:57,1020021170&2015-06-01/16:00:06,1020021717&2015-06-01/16:03:42,1020021430&2015-06-01/16:42:19

… … (the ellipses here indicate that the real-time data text content of the people positioning system is not shown in its entirety)

It should be understood that the above-mentioned embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it will be obvious to those skilled in the art that other variations or modifications may be made on the basis of the above description, and all embodiments may not be exhaustive, and all obvious variations or modifications may be included within the scope of the present invention.

Claims

1. A real-time data simulation method of a coal mine information system is characterized by comprising the following steps:

2. The real-time data simulation method of the coal mine informatization system according to claim 1, characterized in that the basic information of the safety monitoring system comprises main attributes of measuring points of the safety monitoring system, and the main attributes of the measuring points comprise measuring point numbers, measuring point types, measuring point value ranges and upper and lower alarm limits.

3. The method of claim 2, wherein dynamically simulating real-time data of the safety monitoring system at a set time interval based on the basic information and business logic of the safety monitoring system further comprises: and according to the main attributes of the measuring points of the safety monitoring system and the service logic of the measurement of the measuring points, randomly simulating to generate the current measured values of the measuring points and the current states of the measuring points at set time intervals.

4. The method for simulating the real-time data of the coal mine informatization system according to the claim 3, characterized in that the current states of the measuring points comprise normal, alarm, breakpoint, reset and adjustment.

5. The method for simulating real-time data of a coal mine informatization system according to any one of claims 1 to 4, characterized in that the text format of the real-time data text of the safety monitoring system is rtdata.

6. The method for simulating the real-time data of the coal mine information system according to claim 1, wherein the basic information of the personnel positioning system comprises coal mine basic information, area basic information, substation basic information and personnel basic information.

7. The real-time data simulation method of the coal mine informatization system according to claim 6, wherein the coal mine basic information comprises a coal mine number, a coal mine name and an underground personnel upper limit, the area basic information comprises an area number, an area name and an area personnel upper limit, the substation basic information comprises a substation number, a substation name, substation coordinates and track point coordinates, and the personnel basic information comprises a personnel card number, a personnel name, a personnel position and a department to which the personnel belongs.

8. The method of claim 7, wherein dynamically simulating real-time data of the personnel location system at a set time interval based on basic information and business logic of the personnel location system further comprises: and randomly simulating to generate the current number of people in the underground well, the current number of people in the area and the current number of people in the substation at set time intervals according to the basic information of the coal mine, the basic information of the area, the basic information of the substation, the basic information of the personnel and the business logic of personnel positioning.

9. The method for simulating real-time data of a coal mine informatization system according to any one of claims 6-8, characterized in that the text format of the real-time data text of the personnel positioning system is ryss.

10. The method of claim 1, wherein the basic information of the safety monitoring system, the basic information of the personnel location system, the real-time data text of the safety monitoring system and the real-time data text of the personnel location system are stored in a database.