阅读说明：本技术 煤矿智能通风装置及节能智能处理系统 (Intelligent ventilation device for coal mine and energy-saving intelligent processing system ) 是由 郝宇 张立辉 黄学满 秦江涛 于 2021-08-25 设计创作，主要内容包括：本发明提供煤矿智能通风装置及节能智能处理系统,涉及煤矿开采通风领域。该煤矿智能通风装置及节能智能处理系统,包括：主通风单元,所述主通风单元用于煤矿巷道矿道内部主体的通风排气；辅助通风单元,所述辅助通风单元通过固定轨道安装在主通风单元的两侧,所述辅助通风单元用于辅助主通风单元对矿道内进行通风；控制室单元,所述控制室单元通过交换机和CAN总线和主通风单元进行连接,所述控制室单元用于处理、接收和发送供于主通风单元的信息。通过煤矿智能通风装置及节能智能处理系统的设置能够快速灵活检测和监测矿井矿道内部空气环境,也能够快速将矿道内气体排出,也能够保证矿井内部排风系统的低成本运行。(The invention provides an intelligent ventilation device for a coal mine and an energy-saving intelligent processing system, and relates to the field of coal mining ventilation. This colliery intelligence ventilation unit and energy-conserving intelligent processing system includes: the main ventilation unit is used for ventilation and exhaust of the main body in the coal mine roadway; the auxiliary ventilation units are arranged on two sides of the main ventilation unit through fixed rails and are used for assisting the main ventilation unit to ventilate the mine; and the control room unit is connected with the main ventilation unit through a switch and a CAN bus, and is used for processing, receiving and sending information supplied to the main ventilation unit. Through the arrangement of the intelligent ventilation device and the energy-saving intelligent processing system for the coal mine, the internal air environment of the mine tunnel can be rapidly and flexibly detected and monitored, gas in the mine tunnel can be rapidly discharged, and low-cost operation of an internal air exhaust system of the mine can be ensured.)

1. Colliery intelligence ventilation unit and energy-conserving intelligent processing system, its characterized in that: colliery intelligent ventilation device includes:

a main ventilation unit (19), the main ventilation unit (19) being used for ventilation and exhaust of the main body in the coal mine tunnel mine;

the auxiliary ventilation units (28) are installed on two sides of the main ventilation unit (19) through the fixed rails (2), and the auxiliary ventilation units (28) are used for assisting the main ventilation unit (19) in ventilating the mine;

a control room unit (37), the control room unit (37) being connected to the main ventilation unit (19) through the switch (16) and the CAN bus, the control room unit (37) being configured to process, receive and transmit information supplied to the main ventilation unit (19);

the main ventilation unit (19) comprises an air inlet cylinder assembly (10), a main exhaust pipe (1), a main fan (20), a main air inlet (17), a gas detection unit II (21), an alarm II (22), a processor II (23), a Bluetooth module II (9), a sound tester (24), an installation shell II (8), a fixed track (2) and rubber strips (25), wherein the main exhaust pipe (1) is installed at the top of a roadway, the fixed tracks (2) are welded on the lower parts of two sides of the main exhaust pipe (1), the fixed tracks (2) are arranged in a transverse T shape, the rubber strips (25) are arranged on the upper parts of the fixed tracks (2), the air inlet cylinder assemblies (10) are distributed on the upper parts of two sides of the main exhaust pipe (1) at equal distances, the main air inlets (17) distributed at equal distances are arranged at the bottom of the main exhaust pipe (1), the upper portion in the main air inlet (17) is provided with a main fan (20), the lower portion of one side of the main fan (20) is fixedly connected with a second installation shell (8), the bottom of the second installation shell (8) is provided with a second Bluetooth module (9), the top of the second Bluetooth module (9) is electrically connected with a second processor (23), the top of the second processor (23) is electrically connected with a second alarm (22), the top in the second installation shell (8) is fixedly connected with a sound tester (24), the sound tester (24) is electrically connected with the second processor (23), and a second gas detection unit (21) is arranged on one side of the second installation shell (8) and below the main air inlet (17);

the auxiliary ventilation unit (28) comprises a processor I (3), a gas detection unit I (4), a Bluetooth module I (5), a mounting shell I (6), an alarm I (7), a communication assembly (12), a mounting box (27), an auxiliary air inlet (59), an auxiliary fan (18), rollers (26) and a motor (60), wherein the lower part of one side of the mounting box (27) is arranged on the lower part of the fixed rail (2) in a sliding manner, the motor (60) is arranged inside one side of the mounting box (27), the rollers (26) are fixedly connected to the driving end of the motor (60) close to one end of the fixed rail (2), the rollers (26) are arranged on the inner upper part of the fixed rail (2), the rollers (26) are attached to the upper part of the rubber strip (25), and the rollers (26) and the mounting box (27) are clamped and attached to the outer side of the fixed rail (2) in a sliding manner, the middle part in the installation box (27) is provided with an auxiliary fan (18), the bottom of the auxiliary fan (18) is welded with an auxiliary air inlet (59), one side, far away from the main exhaust duct (1), of the installation box (27) is fixedly connected with a first processor (3), the other side of the first processor (3) is provided with a first alarm (7), one side of the bottom of the auxiliary air inlet (59) is fixedly connected with a first installation shell (6), the bottom of the first installation shell (6) is fixedly connected with a first Bluetooth module (5), one side of the first installation shell (6) is fixedly connected with a first gas detection unit (4), the first gas detection unit (4) is arranged on one side below the auxiliary air inlet (59), and the top of the auxiliary fan (18) is provided with a communicating component (12);

control room unit (37) are including switch (16), total server (15), display screen (14) and control module (13), total server (15) are connected with display screen (14), control module (13) and switch (16) respectively through the transmission line, switch (16) are connected with second (23) of treater through the transmission line.

2. The intelligent ventilation device for coal mines as set forth in claim 1, wherein: air inlet section of thick bamboo subassembly (10) is including perforated plate (29), slide bar (36), sealing plug (31), mounting panel (30), spring (32), air inlet section of thick bamboo subassembly (10) is cylinder and inside fixedly connected with mounting panel (30), the middle part of mounting panel (30) slides and is provided with slide bar (36), the equal fixedly connected with perforated plate in the outside (29) of slide bar (36), the equal fixedly connected with sealing plug in the inboard (31) of slide bar (36), slide bar (36) periphery just all is provided with spring (32) between perforated plate (29) and mounting panel (30).

3. The intelligent ventilation device for coal mines as set forth in claim 1, wherein: intercommunication subassembly (12) is including rubber seal (33), slide cartridge (11), electric putter (35) and porous installation piece (34), one side that intercommunication subassembly (12) upper portion is close to main exhaust duct (1) all slides and is provided with slide cartridge (11), equal fixedly connected with porous installation piece (34) in slide cartridge (11), the equal fixed connection in the drive end of electric putter (35) one end in porous installation piece (34) one side, the equal fixed connection of electric putter (35) other end is at intercommunication subassembly (12) top one side inner wall, the one end periphery that electric putter (35) were kept away from in slide cartridge (11) all is provided with rubber seal (33), slide cartridge (11) central line all with air inlet section of thick bamboo subassembly (10) central line parallel and the external diameter less than or equal to air inlet section of thick bamboo subassembly (10) of slide cartridge (11).

4. The energy-saving intelligent processing system of the intelligent ventilation device for the coal mine, according to claim 1, is characterized in that: the first processor (3) comprises a first positioning module (40) and a second deep learning unit (39), the second deep learning unit (39) comprises a second air parameter value (53), a second sample storage (54), a second deep learning model (55), a second information acquisition module (58), a second deep learning execution module (57) and a second detection and identification module (56), the second air parameter value (53) is connected with the second sample storage (54), and the second deep learning execution module (57) is respectively connected with the second deep learning model (55), the second detection and identification module (56) and the second information acquisition module (58).

5. The energy-saving intelligent processing system of the intelligent ventilation device for the coal mine, according to claim 1, is characterized in that: the master server (15) comprises an information processing module (45), a database module (44) and a deep learning unit (43), wherein the deep learning unit (43) comprises a decibel information value (46), an air parameter value (48), a sample storage I (47), a deep learning model I (52), an information acquisition module I (49), a deep learning execution module I (50) and a detection and identification module I (51), the sample storage I (47) is respectively connected with the decibel information value (46), the air parameter value I (48) and the deep learning model I (52), and the deep learning execution module I (50) is respectively connected with the deep learning model I (52), the information acquisition module I (49) and the detection and identification module I (51).

6. The intelligent ventilation device and energy-saving intelligent processing system for the coal mine according to claim 1, wherein: a second positioning module (42) is arranged in the second processor (23), a variable frequency control assembly (41) is arranged in the main fan (20), and the variable frequency control assembly (41) is connected with the second processor (23) through a signal transmission line.

7. The energy-saving intelligent processing system of the intelligent ventilation device for the coal mine according to claim 4, characterized in that: the first processor (3) is connected with the motor (60), the auxiliary fan (18) and the electric push rod (35) through signal lines through a control switch (38), the first processor (3) is connected with the first gas detection unit (4), the first alarm (7) and the first Bluetooth module (5) through the signal lines, and the first Bluetooth module (5) is wirelessly connected with the second Bluetooth module (9).

8. The energy-saving intelligent processing system of the intelligent ventilation device for the coal mine, according to claim 1, is characterized in that: the gas detection unit I (4) is a combination of a gas sensor and a temperature and humidity sensor, and the gas detection unit I (4) and the gas detection unit II (21) are identical.

Technical Field

The invention relates to the technical field of coal mining ventilation, in particular to an intelligent coal mine ventilation device and an energy-saving intelligent processing system.

Background

The inside good ventilation of mine can satisfy the colliery and normally produce, high-efficient production, guarantee colliery normal operating, along with the development of science and technology and technique, also along with communication technology's development, the present life aspect can both use the intellectuality, the mine can not be exceptional equally, the inside tunnel of traditional mine is many, the inside environment of ore deposit way is complicated, the inside environment of ore deposit way can decide that the constructor is healthy in the pit, the inside normal gas concentration direct influence coal mine safety's of ore deposit way exploitation.

The existing coal mining needs to be provided with a plurality of groups of coal mine environment monitoring devices, the devices need to consume a large amount of operating cost in operation, the internal monitoring cost of the coal mine is increased in long-term operation, sometimes all detection devices cannot be used in the coal mine, the cost is inevitably increased in ventilation equipment operation, and meanwhile, the timely cleaning of the internal environment is also very important in the monitoring of the internal environment of the coal mine.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an intelligent ventilation device and an energy-saving intelligent processing system for a coal mine, and solves the problems that the existing mine tunnel internal environment monitoring devices are more, the operation cost is high, the mine air environment cannot be intelligently monitored in time, the air extraction cannot be carried out in time, and the intelligent safety regulation and control cannot be flexibly carried out.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: colliery intelligent ventilation device and energy-conserving intelligent processing system, colliery intelligent ventilation device includes:

the main ventilation unit is used for ventilation and exhaust of the main body in the coal mine roadway;

the auxiliary ventilation units are arranged on two sides of the main ventilation unit through fixed rails and are used for assisting the main ventilation unit to ventilate the mine;

the control room unit is connected with the main ventilation unit through a switch and a CAN bus and is used for processing, receiving and sending information supplied to the main ventilation unit;

the main ventilation unit comprises an air inlet barrel assembly, a main exhaust pipe, a main fan, a main air inlet, a gas detection unit II, an alarm II, a processor II, a Bluetooth module II, a sound tester, an installation shell II, a fixed rail and rubber strips, wherein the main exhaust pipe is installed at the top of a roadway, the fixed rail is welded at the lower parts of the two sides of the main exhaust pipe, the fixed rail is transversely T-shaped, the rubber strips are arranged at the upper parts of the fixed rail, the air inlet barrel assemblies are distributed at equal distances at the upper parts of the two sides of the main exhaust pipe, the main air inlet distributed at equal distances at the bottom of the main exhaust pipe, the main fan is arranged at the upper part in the main air inlet, the installation shell II is fixedly connected at the lower part of one side of the main fan, the Bluetooth module II is arranged at the bottom of the installation shell II, and the processor II is electrically connected at the top of the Bluetooth module II, the top of the second processor is electrically connected with a second alarm, the top of the second installation shell is fixedly connected with a sound tester, the sound tester is electrically connected with the second processor, and a second gas detection unit is arranged on one side of the second installation shell and below the main air inlet;

the auxiliary ventilation unit comprises a first processor, a first gas detection unit, a first Bluetooth module, a first installation shell, a first alarm, a communication assembly, an installation box, an auxiliary air inlet, an auxiliary fan, rollers and a motor, wherein the lower part of one side of the installation box is arranged at the lower part of the fixed track in a sliding manner, the motor is arranged inside one side of the installation box, the driving end of the motor, which is close to one end of the fixed track, is fixedly connected with the rollers, the rollers are arranged at the upper part in the fixed track and are attached to the upper part of the rubber strip, the rollers and the installation box are clamped and attached to the outer side of the fixed track to slide, the auxiliary fan is arranged at the middle part in the installation box, the auxiliary air inlet is welded at the bottom of the auxiliary fan, the first processor is fixedly connected to one side of the installation box, which is far away from the main exhaust pipe, the first alarm is arranged on the other side of the first processor, the first installation shell is fixedly connected to one side of the bottom of the auxiliary air inlet, the bottom of the first mounting shell is fixedly connected with a first Bluetooth module, one side of the first mounting shell is fixedly connected with a first gas detection unit, the first gas detection unit is arranged on one side below the auxiliary air inlet, and the top of the auxiliary air blower is provided with a communication assembly;

the control room unit comprises a switch, a main server, a display screen and a control module, wherein the main server is respectively connected with the display screen, the control module and the switch through transmission lines, and the switch is connected with a second processor through the transmission lines.

Preferably, air inlet section of thick bamboo subassembly is including perforated plate, slide bar, sealing plug, mounting panel, spring, air inlet section of thick bamboo subassembly is cylinder and inside fixedly connected with mounting panel, the middle part of mounting panel slides and is provided with the slide bar, the equal fixedly connected with perforated plate in the outside of slide bar, the equal fixedly connected with sealing plug in inboard of slide bar, the slide bar periphery just all is provided with the spring between perforated plate and mounting panel.

Preferably, the intercommunication subassembly is including rubber seal, slide cartridge, electric putter and porous installation piece, one side that intercommunication subassembly upper portion is close to the main exhaust duct all slides and is provided with the slide cartridge, the porous installation piece of equal fixedly connected with in the slide cartridge, the equal fixed connection of porous installation piece one side is at the drive end of electric putter one end, the equal fixed connection of the electric putter other end is at intercommunication subassembly top one side inner wall, the one end periphery that electric putter was kept away from to the slide cartridge all is provided with rubber seal, the slide cartridge central line all with the parallel and slide cartridge's of air inlet section of thick bamboo subassembly central line external diameter less than or equal to air inlet section of thick bamboo subassembly internal diameter.

Preferably, the first processor comprises a first positioning module and a second deep learning unit, the second deep learning unit comprises a second air parameter value, a second sample storage module, a second deep learning model, a second information acquisition module, a second deep learning execution module and a second detection and identification module, the second air parameter value is connected with the second sample storage module, and the second deep learning execution module is respectively connected with the second deep learning model, the second detection and identification module and the second information acquisition module.

Preferably, the master server comprises an information processing module, a database module and a first deep learning unit, the first deep learning unit comprises a decibel information value, a first air parameter value, a first sample storage module, a first deep learning model, a first information acquisition module, a first deep learning execution module and a first detection and identification module, the first sample storage module is respectively connected with the decibel information value, the first air parameter value and the first deep learning model, and the first deep learning execution module is respectively connected with the first deep learning model, the first information acquisition module and the first detection and identification module.

Preferably, a second positioning module is arranged in the second processor, and a variable frequency control assembly is arranged in the main fan and is connected with the second processor through a signal transmission line.

Preferably, the first processor is connected with the motor, the auxiliary fan and the electric push rod through signal lines through a control switch respectively, the first processor is connected with the first gas detection unit, the first alarm and the first Bluetooth module through signal lines, and the first Bluetooth module is wirelessly connected with the second Bluetooth module.

Preferably, the first gas detection unit is a combination of a gas sensor and a temperature and humidity sensor, and the first gas detection unit and the second gas detection unit are the same.

The working principle is as follows: when the intelligent ventilation device and the energy-saving intelligent processing system for the coal mine are used in operation, firstly, a main exhaust pipe is arranged at the inner top of a mine tunnel and is connected with a ventilation shaft of the coal mine through a pipeline, when a ventilation system in the coal mine tunnel operates, firstly, a gas detection unit II can detect the gas in the mine and the air environment such as temperature, humidity and the like, a variable frequency control assembly starts and stops to enable a main fan to operate, the main fan can pump the air in the mine tunnel away through normal operation to enable the environment in the mine tunnel to be safe, the gas detection unit II can transmit the air parameter information in the mine tunnel, the air parameter information sets different gradients, an alarm gives out sounds with different frequencies in the gradients, a sound tester obtains the decibel value of the sound through the sound, and the gas detection unit II transmits the air parameter information to a processor II, the sound tester can transmit decibel values to a second processor, the second processor transmits two data and position information in a second positioning module to a control room unit through a downhole exchanger, a main server in the control room unit receives the information and then judges the two parameter information, the information processing module quickly judges whether the air environment represented by the parameter information is in the safe environment, if the parameter information exceeds the safe parameter information in the mine, the main server enables a frequency conversion control assembly to enable a main fan to increase the air draft intensity through the exchanger and the second processor, the second processor performs signal transmission through a second Bluetooth module and a first Bluetooth module, auxiliary ventilation units around the second processor are enabled to move to the main ventilation unit, and after the first processor receives the information of the second Bluetooth module through the first Bluetooth module, the first processor enables a motor to work through a control switch and the positioning information, the motor moves on the fixed rail towards the main ventilation unit sending information through the roller, the position of the auxiliary ventilation unit is determined through the positioning module I in the processor I and the positioning module II in the processor II, when the connecting assembly moves to the air inlet barrel assembly adjacent to and closest to the main ventilation unit through the installation box, the sliding barrel is inserted into the air inlet barrel assembly through the sliding of the electric push rod, the porous plate in the air inlet barrel assembly is extruded by the sliding barrel, the sealing plug is separated from the air inlet barrel assembly through the sliding rod by the porous plate, at the moment, the parameter information received by the processor I through the Bluetooth module I enables the auxiliary fan to be started through the control switch, so that air in a mine is greatly pumped into the main exhaust pipe, the air in the mine is greatly pumped out, the cleanness of the environment in the mine is guaranteed, when the main server sends information to the processor II, according to the numerical value of the air parameter, the corresponding command processor II selects the nearby processor I for positioning communication, timely purification of air in the mine shaft can be guaranteed, a good response can be guaranteed when an emergency air problem occurs in the mine shaft, if the provided information parameter value is in the safety environment in the mine shaft, a deep learning model I is established through the decibel information value and the air parameter value I after the parameter is stored by a deep learning unit I in the master server, the deep learning model I is established through the decibel information value and the air parameter value I for the air parameters with different concentrations in the mine shaft, the control module obtains different parameter information values through monitoring, when the next decibel information value and the air parameter value are sent to the master server, the information acquisition module I can be directly subjected to deep learning analysis through the deep learning execution module I, the first detection and identification module transmits information out to the main server, the main server transmits information parameters to a second processor inside the mine shaft through a switch, the second processor regulates and controls a variable frequency control assembly through the received parameters to control the running power of a main fan, the second processor transmits information to the first processor, the first processor controls the start and stop of a secondary fan through a control switch according to the information and can also keep distance according to mutual positions, the first processor receives the information of the second processor each time, a second deep learning model is established through the second deep learning model, when the corresponding position or time each time, the first positioning module automatically reflects the position close to the mine shaft where air is possibly dangerous, in the second deep learning unit, the first gas detection unit can detect the air environment in the mine shaft, and the positioning module positions in the mine shaft, the alarm is given out through the first alarm, someone in the mine tunnel can receive the alarm, the second deep learning unit can receive information of the second processor and receive a second air parameter value provided by the first gas detection unit, at the moment, through establishing the second deep learning model, the auxiliary ventilation unit can automatically identify the problem that the air environment parameters possibly exceed standards at a certain position and different air parameters, the auxiliary ventilation unit is used for independently detecting the air environment parameters in a circulating mode, the environment in the mine tunnel can be detected for many times, the internal environment of the mine tunnel is guaranteed to be constantly in a safe value, and the mine tunnel is worthy of great popularization.

(III) advantageous effects

The invention provides an intelligent ventilation device for a coal mine and an energy-saving intelligent processing system. The method has the following beneficial effects:

1. the invention can detect the gas in the mine and the air environment such as the temperature and the humidity by the gas detection unit II, the frequency conversion control assembly enables the main blower to run by starting and stopping, the main blower can pump the air in the mine tunnel away by normal running, the environment in the mine tunnel of the mine is safe, the sound tester obtains the decibel value of the sound by the sound, the comparison of the two data can enable the air environment in the mine tunnel to be accurately and efficiently monitored, the processor II transmits the two data and the position information in the positioning module II to the control room unit by the underground switch, the main server in the control room unit judges the information of the two parameters after receiving the information, whether the air environment represented by the parameter information is in the safe environment or not is quickly judged through the information processing module, and the safety of the environmental parameters in the mine can be ensured at any time.

2. According to the invention, the frequency conversion control assembly enables the main fan to increase the air draft force through the main server and the processor II, the processor I enables the motor to work through the control switch and the positioning information, the motor moves on the fixed rail towards the main ventilation unit sending information through the roller, the electric push rod enables the sliding barrel to slide, the sliding barrel is inserted into the air inlet barrel assembly, the porous plate in the air inlet barrel assembly is extruded by the sliding barrel at the moment, the sealing plug is separated from the air inlet barrel assembly through the sliding rod by the porous plate, the secondary fan is started through the parameter information received by the processor I through the Bluetooth module I through the control switch, so that a large amount of air in a mine is pumped into the main exhaust pipe, the harmful air in the mine is timely pumped out, the cleanness of the internal environment of the mine is ensured, the safe and efficient production of the mine is ensured, and a safe operation environment of workers is ensured.

3. When the main server sends information to the second processor, the second processor correspondingly orders the second processor to select the first processor nearby for positioning communication according to the numerical value of the air parameter, so that the timely purification of the air in the mine tunnel can be ensured, the reaction can be well ensured when the emergency air problem occurs in the mine tunnel, the mine safety can be ensured in time, when the local air environment in the mine is unsafe, the air can be purified in time, and the safety of the environment in the mine can be ensured constantly.

4. The invention establishes a deep learning model through decibel information values and air parameter values, after the air parameters with different concentrations in the mine shaft are established into the deep learning model through the decibel information values and the air parameter values I, the concentration gradient of harmful gas in the mine shaft is alarmed out through an alarm, the sound of the alarm can be directly measured through a cross beam to obtain the decibel value so as to obtain the gas concentration in the mine shaft, so that the monitoring of the internal environment of the mine shaft is more accurate, thus the gas parameters and the decibel values in the specific mine shaft are indirectly combined, the monitoring accuracy in the mine shaft is ensured, a master server sends the information parameters to a second processor in the mine shaft through a switch, the second processor regulates and controls a variable frequency control component through the received parameters, controls the running power of a main fan, and ensures the safe environment in the mine shaft, the main fan can reduce working strength, and the cost of electric power in the mine shaft can be saved and reduced while the fan is guaranteed to operate in a safe environment all the time.

5. According to the invention, the deep learning model is established through the deep learning model II, the position close to a mine tunnel where air is possibly dangerous is automatically reflected through the positioning module I when the position or the time corresponds to each time, the air environment in the mine tunnel can be detected through the gas detection unit I in the deep learning unit II, the position in the mine tunnel is positioned through the positioning module, an alarm is given out through the alarm, the problem that the air environment parameters possibly exceed the standard is automatically identified, and the roller is flexibly moved to the mine tunnel where the air environment exceeds the standard through the motor driving, so that the intelligent regulation and control and the safety of the air environment in the mine tunnel are ensured.

6. According to the invention, through intelligent matching between the main ventilation unit and the main server, when the main ventilation unit operates, corresponding power is started according to the internal air environment of the mine tunnel, so that the main ventilation unit can operate economically and at low cost, the operation cost of the mine tunnel ventilation system is saved, intelligent and flexible purification of the internal air of the mine can be realized through matching between the auxiliary ventilation unit and the main ventilation unit, the internal purification of the mine environment can also be realized, the flexible arrangement of the auxiliary ventilation unit ensures that the purification equipment in the mine can be flexibly arranged and used, the maximum efficacy of the equipment is realized, and the intelligent ventilation system is worthy of great popularization.

Drawings

FIG. 1 is a schematic view of the frame structure of the present invention;

FIG. 2 is a cross-sectional structural view of the present invention;

FIG. 3 is a perspective view of the communication assembly and air intake barrel assembly of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 2;

FIG. 5 is an enlarged view of FIG. 2 at B;

FIG. 6 is a system diagram of the present invention;

FIG. 7 is a system block diagram of the auxiliary ventilation unit of the present invention;

FIG. 8 is a system block diagram of the primary ventilation unit of the present invention;

FIG. 9 is a system block diagram of a control room unit of the present invention;

FIG. 10 is a system block diagram of a first processor of the present invention;

FIG. 11 is a system block diagram of the overall server of the present invention;

FIG. 12 is a system block diagram of a deep learning unit one of the present invention;

fig. 13 is a system block diagram of a deep learning unit ii according to the present invention.

Wherein, 1, a main exhaust duct; 2. fixing a track; 3. a first processor; 4. a first gas detection unit; 5. a first Bluetooth module; 6. mounting a first shell; 7. an alarm I; 8. mounting a second shell; 9. a second Bluetooth module; 10. an air intake barrel assembly; 11. a slide cylinder; 12. a communicating component; 13. a control module; 14. a display screen; 15. a main server; 16. a switch; 17. a main air inlet; 18. an auxiliary fan; 19. a main ventilation unit; 20. a main fan; 21. a second gas detection unit; 22. a second alarm; 23. a second processor; 24. a sound tester; 25. a rubber strip; 26. a roller; 27. installing a box; 28. an auxiliary ventilation unit; 29. a perforated plate; 30. mounting a plate; 31. a sealing plug; 32. a spring; 33. a rubber seal ring; 34. a porous mounting block; 35. an electric push rod; 36. a slide bar; 37. a control room unit; 38. a control switch; 39. a deep learning unit II; 40. a first positioning module; 41. a variable frequency control component; 42. a second positioning module; 43. a first deep learning unit; 44. a database module; 45. an information processing module; 46. decibel information values; 47. storing a sample I; 48. a first air parameter value; 49. a first information acquisition module; 50. a deep learning execution module I; 51. a first detection and identification module; 52. deep learning model one; 53. a second air parameter value; 54. sample storage two; 55. a second deep learning model; 56. a second detection and identification module; 57. a deep learning execution module II; 58. a second information acquisition module; 59. a secondary air inlet; 60. an electric motor.

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.

Example (b):

as shown in fig. 1 to 13, an embodiment of the present invention provides an intelligent ventilation device for a coal mine and an energy-saving intelligent processing system, where the intelligent ventilation device for a coal mine includes:

the main ventilation unit 19 is used for ventilation and exhaust of the main body in the coal mine roadway and mine tunnel;

the auxiliary ventilation unit 28, the auxiliary ventilation unit 28 is installed on both sides of the main ventilation unit 19 through the fixed rail 2, the auxiliary ventilation unit 28 is used for assisting the main ventilation unit 19 to ventilate the mine;

a control room unit 37, the control room unit 37 being connected to the main ventilation unit 19 through the switch 16 and the CAN bus, the control room unit 37 being configured to process, receive, and transmit information supplied to the main ventilation unit 19;

the main ventilation unit 19 comprises an air inlet barrel assembly 10, a main exhaust duct 1, a main fan 20, a main air inlet 17, a gas detection unit II 21, an alarm II 22, a processor II 23, a Bluetooth module II 9, a sound tester 24, a mounting shell II 8, a fixed rail 2 and rubber strips 25, wherein the main exhaust duct 1 is mounted at the top of a roadway of a mine, the main exhaust duct 1 is mounted at the inner top of the mine, the main exhaust duct 1 is connected to a ventilation shaft of a coal mine through a pipeline, the main fan 20 and the main air inlet 17 are arranged in such a way that harmful air in the mine can be extracted out constantly and discharged through the ventilation shaft of the mine, the fixed rails 2 are welded to the lower parts of two sides of the main exhaust duct 1, the fixed rails 2 are arranged in a transverse T shape, the rubber strips 25 are arranged on the upper parts of the fixed rails 2, and the air inlet barrel assemblies 10 are distributed at equal distances on the upper parts of two sides of the main exhaust duct 1, the bottom of the main exhaust duct 1 is provided with main air inlets 17 distributed equidistantly, the upper part in each main air inlet 17 is provided with a main fan 20, the lower part of one side of each main fan 20 is fixedly connected with a second installation shell 8, the main fan 20 can pump air in the mine shaft away through normal operation, so that the environment in the mine shaft is safe, a second gas detection unit 21 can transmit air parameter information in the mine shaft, the bottom of the second installation shell 8 is provided with a second Bluetooth module 9, the top of the second Bluetooth module 9 is electrically connected with a second processor 23, the top of the second processor 23 is electrically connected with a second alarm 22, the top in the second installation shell 8 is fixedly connected with a sound tester 24, the sound tester 24 is electrically connected with the second processor 23, the air parameter information is provided with different gradients, the alarms with different frequencies in the gradients send out sounds, and the sound tester 24 obtains decibel values of the sounds according to the sound levels, the second gas detection unit 21 transmits air parameter information to the second processor 23, the sound tester 24 can transmit a decibel information value 46 to the second processor 23, the second gas detection unit 21 is arranged on one side of the second mounting shell 8 and below the main air inlet 17, when a ventilation system in the mine tunnel runs, the second gas detection unit 21 can detect the gas environment in the mine, such as temperature and humidity, firstly, the second gas detection unit 21 can detect the gas environment in the mine, the main air blower 20 runs through starting and stopping the variable frequency control assembly 41, harmful gas concentration gradient in the mine tunnel is alarmed out through the alarm, the sound of the alarm can be directly measured through the cross beam to obtain the decibel value to obtain the gas concentration in the mine tunnel, so that the monitoring of the environment in the mine tunnel is more accurate, the gas parameters and the decibel value in the specific mine are indirectly combined to ensure the accuracy of the monitoring in the mine, when the decibel value is increased, the sound of the alarm is certainly increased at this moment, which means that the concentration of harmful gas in the air at a certain local position in the mine exceeds the standard, the deep learning unit I43 in the master server 15 can intelligently identify the dangerous position of the coal mine, the deep learning unit I43 in the master server 15 and the deep learning unit II 39 in the processor I3 can accurately and flexibly schedule and regulate the main fan 20 and the auxiliary fan 18 in the mine tunnel, and the deep learning unit II 39 in the processor I3 is intelligently matched with a possible dangerous area of conventional air to ensure the timely dissipation of the air in the mine tunnel, and at this moment, the control module 13 in the master server 15 can flexibly regulate and control the main exhaust duct 1 and the dangerous point to be far away from the related main fan 20 according to the information displayed by the display screen 14, the auxiliary fan 18 and the main fan 20 assist in flexibly and coordinately exhausting air at the dangerous part, so that the safety of the interior of a mine is ensured; through the combination of sound shellfish and alarm for the process of gathering directly passes through the crossbeam survey, has reduced the quantity of circuit line, can deal with harsher environment, and the parameter through the sound wave can realize comparatively quick accurate judgement position simultaneously, thereby realizes emergency response.

The auxiliary ventilation unit 28 comprises a first processor 3, a first gas detection unit 4, a first Bluetooth module 5, a first installation shell 6, a first alarm 7, a communication component 12, an installation box 27, a second air inlet 59, a second fan 18, rollers 26 and a motor 60, wherein the second processor 23 performs signal transmission through a second Bluetooth module 9 and a first Bluetooth module 5, so that the auxiliary ventilation units 28 around the second processor 23 all move to the main ventilation unit 19, the lower part of one side of the installation box 27 is all arranged at the lower part of the fixed track 2 in a sliding manner, the motor 60 is arranged inside one side of the installation box 27, the driving end of one end of the motor 60 close to the fixed track 2 is all fixedly connected with the rollers 26, the rollers 26 are all arranged at the upper part in the fixed track 2, the rollers 26 are all attached to the upper part of the rubber strip 25, the rollers 26 and the installation box 27 are clamped and attached to the outer side of the fixed track 2 to slide, after the first processor 3 receives information of the second Bluetooth module 9 through the first Bluetooth module 5, the first processor 3 enables the motor 60 to work through the control switch 38 and the positioning information, the motor 60 moves on the fixed track 2 towards the main ventilation unit 19 sending information through the idler wheel 26, the positions of the auxiliary ventilation units 28 are determined through the first positioning module 40 in the first processor 3 and the second positioning module 42 in the second processor 23, the auxiliary fans 18 are arranged in the middle of the installation box 27, the bottom of each auxiliary fan 18 is welded with an auxiliary air inlet 59, one side, far away from the main exhaust duct 1, of the installation box 27 is fixedly connected with the first processor 3, the other side of the first processor 3 is provided with a first alarm 7, one side of the bottom of each auxiliary air inlet 59 is fixedly connected with a first installation shell 6, the bottom of the first installation shell 6 is fixedly connected with a first Bluetooth module 5, one side of the first installation shell 6 is fixedly connected with a first gas detection unit 4, and the first gas detection unit 4 is arranged on one side below the auxiliary air inlet 59, the top of the auxiliary fan 18 is provided with a communication component 12;

the control room unit 37 comprises a switch 16, a main server 15, a display screen 14 and an operation and control module 13, when the main server 15 sends information to a second processor 23, the second processor 23 is correspondingly instructed to select a first processor 3 nearby for positioning communication according to the numerical value of the air parameter, so that the timely purification of the air in the mine shaft can be ensured, and the good response can be ensured when an emergency air problem occurs in the mine shaft, the main server 15 is respectively connected with the display screen 14, the operation and control module 13 and the switch 16 through transmission lines, the switch 16 is connected with the second processor 23 through the transmission lines, the second processor 23 transmits two data and the position information in the second positioning module 42 to the control room unit 37 through the underground switch 16, the main server 15 in the control room unit 37 judges the information of the two parameters after receiving the information, and the information processing module 45 quickly judges whether the air environment represented by the parameter information is in a safe environment, if the parameter information exceeds the safety parameter information in the mine tunnel, the main server 15 enables the frequency conversion control component 41 to enable the main fan 20 to increase the air draft strength through the exchanger 16 and the second processor 23.

The air inlet barrel assembly 10 comprises a porous plate 29, a slide rod 36, a sealing plug 31, a mounting plate 30 and a spring 32, the air inlet barrel assembly 10 is cylindrical, the mounting plate 30 is fixedly connected inside, the slide rod 36 is arranged in the middle of the mounting plate 30 in a sliding mode, the porous plate 29 is fixedly connected to the outer side of the slide rod 36, the sealing plug 31 is fixedly connected to the inner side of the slide rod 36, the spring 32 is arranged on the periphery of the slide rod 36 and between the porous plate 29 and the mounting plate 30, when the connecting assembly 12 moves to the nearest air inlet barrel assembly 10 adjacent to the main ventilation unit 19 through the mounting box 27, the slide cylinder 11 is inserted into the air inlet barrel assembly 10 by sliding the electric push rod 35, the porous plate 29 in the air inlet barrel assembly 10 is extruded by the slide cylinder 11, the porous plate 29 enables the sealing plug 31 to be separated from the air inlet barrel assembly 10 through the slide rod 36, and the auxiliary fan 18 is started through a control switch 38 according to parameter information received by the first bluetooth sealing plug module 5, the air in the mine is pumped into the main exhaust duct 1 in a large amount, so that the air in the mine tunnel is pumped out in a large amount, the auxiliary ventilation unit 28 and the main ventilation unit 19 are matched and combined to realize efficient purification of the internal environment of the mine tunnel, and the safety of the internal environment of the mine tunnel and the normal operation of operation in the mine are ensured all the time.

Intercommunication subassembly 12 is including rubber seal 33, slide cartridge 11, electric putter 35 and porous installation piece 34, intercommunication subassembly 12 upper portion is close to one side of main exhaust duct 1 and all slides and is provided with slide cartridge 11, equal fixedly connected with porous installation piece 34 in the slide cartridge 11, the equal fixed connection in the drive end of electric putter 35 one end in porous installation piece 34 one side, the equal fixed connection of electric putter 35 other end is at intercommunication subassembly 12 top one side inner wall, the one end periphery that electric putter 35 was kept away from to slide cartridge 11 all is provided with rubber seal 33, slide cartridge 11 central line all with the parallel and slide cartridge 11's of air inlet subassembly 10 central line external diameter less than or equal to air inlet subassembly 10 internal diameter.

The first processor 3 comprises a first positioning module 40 and a second deep learning unit 39, the second deep learning unit 39 comprises a second air parameter value 53, a second sample storage 54, a second deep learning model 55, a second information acquisition module 58, a second deep learning execution module 57 and a second detection and identification module 56, the second air parameter value 53 is connected with the second sample storage 54, the second deep learning execution module 57 is respectively connected with the second deep learning model 55, the second detection and identification module 56 and the second information acquisition module 58, the first processor 3 receives information of the second processor 23 each time, the second deep learning model 55 is established through the second deep learning model 55, the first positioning module 40 automatically reacts to a position close to a mine where air is possibly dangerous at each corresponding position or time, and the air environment in the mine can be detected through the first gas detection unit 4 in the second deep learning unit 39, the position in the mine tunnel is located through the first locating module 40, an alarm is given out through the first alarm 7, people in the mine tunnel can receive the alarm, meanwhile, the second deep learning unit 39 receives the information of the second processor 23 and receives the second air parameter value 53 provided by the first gas detection unit 4, and at the moment, the second deep learning model 55 is built, so that the auxiliary ventilation unit 28 can automatically identify the problem that the air environment parameters exceed the standard at a certain position and different air parameters.

The main server 15 comprises an information processing module 45, a database module 44 and a deep learning unit 43, the deep learning unit 43 comprises a decibel information value 46, an air parameter value 48, a sample storage 47, a deep learning model 52, an information acquisition module 49, a deep learning execution module 50 and a detection and identification module 51, the sample storage 47 is respectively connected with the decibel information value 46, the air parameter value 48 and the deep learning model 52, the deep learning execution module 50 is respectively connected with the deep learning model 52, the information acquisition module 49 and the detection and identification module 51, if the provided information parameter value is in the safety environment inside the mine shaft, the deep learning unit 43 in the main server 15 stores the parameter, then the deep learning model 52 is established through the decibel information value 46 and the air parameter value 48, and the air parameters with different concentrations inside the mine shaft are established through the decibel information value 46 and the air parameter value 48 After the first deep learning model 52 is established, the control module 13 acquires different parameter information values through monitoring, when the next decibel information value 46 and the first air parameter value 48 are sent to the main server 15, the first information acquisition module 49 can be subjected to deep learning analysis directly through the first deep learning execution module 50, the first detection and identification module 51 conducts information out to give the main server 15, and the main server 15 sends the information parameters to the second processor 23 in the mine shaft through the switch 16.

A second positioning module 42 is arranged in the second processor 23, a second frequency conversion control assembly 41 is arranged in the main fan 20, the second frequency conversion control assembly 41 is connected with the second processor 23 through a signal transmission line, the second processor 23 regulates and controls the frequency conversion control assembly 41 through received parameters to control the running power of the main fan 20, meanwhile, the second processor 23 sends information to the first processor 3, the first processor 3 controls the auxiliary fan 18 to start and stop through the control switch 38 according to the information, and meanwhile, distance keeping can be carried out according to the mutual positions.

Treater 3 respectively with motor 60 through control switch 38, secondary fan 18 and electric putter 35 pass through the signal line connection, treater 3 passes through signal line and gas detection unit 4, alarm 7 is connected with bluetooth module 5, bluetooth module 5 and the two 9 wireless connection of bluetooth module, it independently detects the air circumstance parameter to make a tour through supplementary ventilation unit 28, also can guarantee to detect the environment in the mine shaft many times, guarantee that the inside environment of mine shaft is constantly in safe numerical value.

The first 4 gas detection units are combined with the temperature and humidity sensors, the first 4 gas detection units and the second 21 gas detection units are identical, and the two same settings can fully ensure that the internal environment of the mine tunnel is detected and the safety of the internal air environment of the mine tunnel is ensured.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.