CN111845578B

CN111845578B - Atmosphere pollution intelligent monitoring equipment based on 5G communication

Info

Publication number: CN111845578B
Application number: CN202010727729.4A
Authority: CN
Inventors: 陈圆圆; 路凤祎; 宋欣; 路洋; 王兰秀; 王爱珍; 孙娜
Original assignee: Hebei Huaqing Environmental Science And Technology Group Co ltd
Current assignee: Hebei Huaqing Environmental Science and Technology Group Co.,Ltd.
Priority date: 2020-07-23
Filing date: 2020-07-23
Publication date: 2021-10-01
Anticipated expiration: 2040-07-23
Also published as: CN111845578A

Abstract

The invention relates to the technical field of novel communication detection devices, in particular to an intelligent atmospheric pollution monitoring device based on 5G communication. According to the invention, through the design of a multidirectional discrete stable supporting structure carried by a vehicle body, the device is convenient to carry on a vehicle roof frame, and through a matching structure supported by multidirectional component force, the shaking impact on equipment in the running process of the vehicle is greatly reduced, the moving measurement accuracy of the equipment is ensured, and the service life is prolonged, and through the design of a communication conduction type photoelectric detection structure, the device is convenient to detect the particle impurity pollution in the air, converts the detection result into a signal, and then conducts 5G technology-based derivation, so that the detection effect and the derivation speed are further improved.

Description

Atmosphere pollution intelligent monitoring equipment based on 5G communication

Technical Field

The invention relates to the technical field of novel communication detection devices, in particular to intelligent atmospheric pollution monitoring equipment based on 5G communication.

Background

Atmospheric pollution monitoring refers to the kind and the concentration of pollutant in the survey atmosphere, observe its time-space distribution and the process of change law, the pollutant in the atmosphere is discerned to atmospheric pollution monitoring's aim at, master its distribution and diffusion law, the emission and the control condition of monitoring the atmosphere pollution source, however, current device often is fixed in certain fixed place and detects, lack corresponding scour protection and stabilize and carry on the structure, be not convenient carry on the roof-rack follow the car and carry out the continuous detection of removal process, and the detection efficiency and the structure conduction efficiency of current device are lower.

SUMMARY OF THE PATENT FOR INVENTION

The invention aims to provide an intelligent atmospheric pollution monitoring device based on 5G communication.

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

an intelligent atmospheric pollution monitoring device based on 5G communication comprises an assembly camera bellows, wherein a leading-in fan is fixed at the top end of the assembly camera bellows through screws, a discharging fan is fixed at the bottom end of the assembly camera bellows through screws, a light transmission measuring bin is clamped between the leading-in fan and the discharging fan, two sides of the assembly camera bellows are connected with contact positioning plates through rotating pins, extension carrying rods are welded at the upper end and the lower end of one end of the assembly camera bellows, a laser emitting end is fixed between the extension carrying rods and the extension carrying rods, a first lens frame is fixed at one end of the laser emitting end, a second lens frame is fixed inside the other end of the assembly camera bellows, a photoelectric receiving plate is fixedly connected with the photoelectric receiving plate through the second lens frame and is positioned at one end of the second lens frame, a multi-circuit carrying box is fixed at one end of the photoelectric receiving plate, and a signal processing circuit board is mounted inside the multi-circuit carrying box, one end of the multi-circuit carrying box is fixed with a GPRS export module;

the bottom end of the contact positioning plate is fixed with a vehicle body-carried multidirectional discrete stable supporting structure which comprises a multidirectional stable supporting frame, an inflatable spring pad, a stable extension carrying block, a force unloading sliding block, a matching stroke limiting block, a positioning carrying end block, a clamping stroke block, a locking clamping block, a matching stable bracket, a contact conduction pressing plate, a stressed push rod, a pressure-bearing sliding plate, a first spring, a discrete derivation sliding rod, an internal carrying shell, a second spring and a third spring, the top end of the multidirectional stable supporting frame is fixedly connected with the inflatable spring pad through screws, four ends of the multidirectional stable supporting frame are all welded with the stable extension carrying block, the top of one end of the stable extension carrying block is welded with the force unloading sliding block, the bottom of one end of the stable extension carrying block is welded with the third spring, one end of the positioning carrying end block is welded with the matching stroke limiting block, the matched stroke limiting block is connected with the force unloading sliding block in a sliding mode, the other end of the third spring is connected with the positioning and carrying end block in a welding mode, two sides of the bottom end of the positioning and carrying end block are connected with the clamping stroke block in a welding mode, two ends of the bottom end of the clamping stroke block are connected with the locking clamping blocks in a sliding mode, the bottom end of the multidirectional stable supporting frame is connected with the matched stable supporting frame in a welding mode, the bottom end of the multidirectional stable supporting frame is further connected with the built-in carrying shell in a welding mode, the two built-in carrying shells are located on two sides of the matched stable supporting frame respectively, the inside of the matched stable supporting frame is connected with the pressure-bearing sliding plate in a sliding mode, the inside of the pressure-bearing sliding plate is connected with the stress push rod in a welding mode, the top end of the stress push rod is attached to the first spring, the bottom end of the stress push rod is connected with the contact conduction pressing plate in a welding mode, and the discrete derivation sliding rods are respectively welded on two sides of the top end of the contact conduction pressing plate, one end of the contact conduction pressure plate is connected with the built-in carrying shell through a second spring.

Preferably, the inside of assembling the bottom end of the stabilizing support is provided with a limiting sliding through hole, and the limiting sliding through hole is in clearance fit with the stressed push rod.

Preferably, a plurality of dovetail sliding blocks are welded on two sides of the pressure-bearing sliding plate, dovetail sliding grooves are formed in inner walls of two sides of the assembled stable support, and the dovetail sliding blocks are in clearance fit with the dovetail sliding grooves.

Preferably, the inside of adapting the stroke stopper is seted up and is unloaded power slip and push away the guide slot, the both sides welding of unloading the power slider is joined in marriage the lug, join in marriage the lug and unload power slip and push away the guide slot and be clearance fit.

Preferably, the top welding of locking clamp splice has the T type to deduce the displacement piece, cooperation T type spout has all been seted up at the both ends of clamping stroke piece lower surface, cooperation T type spout is clearance fit with the T type and deduces the displacement piece.

Preferably, a force guide rail rod is welded at the top end of the discrete derivation sliding rod, a matching connection push piece is welded at the top end of the force guide rail rod, a component force slide hole is formed in the bottom end of the built-in carrying shell, the component force slide hole and the force guide rail rod are in clearance fit, the diameter of the matching connection push piece is five centimeters, and the diameter of the component force slide hole is three centimeters.

Preferably, a signal amplification circuit is mounted in the multi-circuit mounting case, the photo-electric receiving plate is electrically connected to the signal amplification circuit, and the model number of the photo-electric receiving plate is SD 5600/5610.

Preferably, a microprocessor and a signal deriving module are mounted inside the signal processing circuit board, the microprocessor is electrically connected with the signal amplifying circuit and the signal deriving module, a signal of the microprocessor is a8386DX16, and a model of the signal deriving module is SIGA-CC 1C.

Preferably, the signal derivation module is electrically connected with the GPRS derivation module, and one side of the GPRS derivation module is rotatably connected with the signal diffusion antenna.

The invention has at least the following beneficial effects:

1. according to the invention, through the design that the vehicle body carries the multidirectional discrete stable supporting structure, the device is convenient to carry on the roof frame, and through the matching structure of multidirectional component force support, the shaking impact on the equipment in the running process of the vehicle is greatly reduced, so that the moving measurement accuracy of the equipment is ensured, and meanwhile, the service life is prolonged;

2. according to the invention, through the design of the communication conduction type photoelectric detection structure, the device is convenient for detecting particle impurity pollution in the air, and meanwhile, the detection result is converted into a signal and then is exported based on a 5G technology base, so that the detection effect and the export rate are further improved.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the patent of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the patent of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a side view of the present invention in its entirety;

FIG. 3 is a rear elevational view of the invention as a whole;

FIG. 4 is a partial cross-sectional view of a communication conducting type photodetection structure according to the present invention;

FIG. 5 is a partial schematic structural view of a communication conducting type photodetection structure according to the present invention;

FIG. 6 is a schematic view of the vehicle body carrying a multidirectional discrete stabilizing support structure of the present invention;

FIG. 7 is a partial cross-sectional view of the vehicle body-mounted multi-directional discrete stabilizing support structure of the present invention.

In the figure: 1. assembling a dark box; 2. a lead-in fan; 3. a light transmission measurement bin; 4. a discharge fan; 5. contacting the positioning plate; 6. an extension carrying rod; 7. a laser emitting end; 8. a first lens holder; 9. a second lens holder; 10. a photoelectric receiving plate; 11. a multi-circuit mounting case; 12. a signal processing circuit board; 13. a GPRS export module; 14. a multidirectional stable support frame; 15. an inflatable spring mattress; 16. a stable extension carrying block; 17. a force unloading slide block; 18. a matching stroke limiting block; 19. a positioning and carrying end block; 20. clamping a stroke block; 21. locking the clamping block; 22. assembling a stable bracket; 23. contacting the conductive platen; 24. a stressed push rod; 25. a pressure-bearing slide plate; 26. a first spring; 27. separately deducing a slide bar; 28. a carrying shell is arranged in the shell; 29. a second spring; 30. a third spring; 31. the vehicle body carries a multidirectional discrete stable support structure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

Referring to fig. 1-7, an intelligent atmospheric pollution monitoring device based on 5G communication comprises an assembly camera bellows 1, wherein a leading-in fan 2 is fixed at the top end of the assembly camera bellows 1 through screws, a discharging fan 4 is fixed at the bottom end of the assembly camera bellows 1 through screws, a light transmission measuring bin 3 is clamped between the leading-in fan 2 and the discharging fan 4, two sides of the assembly camera bellows 1 are connected with contact positioning plates 5 through rotating pins, extension carrying rods 6 are welded at the upper end and the lower end of one end of the assembly camera bellows 1, a laser emitting end 7 is fixed between the extension carrying rods 6 and the extension carrying rods 6, a first lens frame 8 is fixed at one end of the laser emitting end 7, a second lens frame 9 is fixed inside the other end of the assembly camera bellows 1 and is fixedly connected with a photoelectric receiving plate 10 through the second lens frame 9, the photoelectric receiving plate 10 is located at one end of the second lens frame 9, a multi-circuit carrying box 11 is fixed at one end of the photoelectric receiving plate 10, a signal processing circuit board 12 is mounted in the multi-circuit carrying box 11, and a GPRS export module 13 is fixed at one end of the multi-circuit carrying box 11, so that the rapid detection of the content of dust particles mixed in the air is conveniently completed, and meanwhile, the detection result is conveniently exported to the cloud for storage;

the bottom end of the contact positioning plate 5 is fixed with a vehicle body carrying multidirectional discrete stable supporting structure 31, the vehicle body carrying multidirectional discrete stable supporting structure 31 comprises a multidirectional stable supporting frame 14, an inflatable spring cushion 15, a stable extension carrying block 16, a force unloading sliding block 17, a matching stroke limiting block 18, a positioning carrying end block 19, a clamping stroke block 20, a locking clamping block 21, a matching stable supporting frame 22, a contact conduction pressing plate 23, a stress push rod 24, a pressure bearing sliding plate 25, a first spring 26, a discrete derivation sliding rod 27, an inner mounting shell 28, a second spring 29 and a third spring 30, the top end of the multidirectional stable supporting frame 14 is fixedly connected with the inflatable spring cushion 15 through screws, four ends of the multidirectional stable supporting frame 14 are all welded with the stable extension carrying block 16, the top end of one end of the stable extension carrying block 16 is welded with the force unloading sliding block 17, the bottom end of one end of the stable extension carrying block 16 is welded with the third spring 30, one end of a positioning carrying end block 19 is welded with a matching stroke limiting block 18, the matching stroke limiting block 18 is in sliding connection with a force unloading sliding block 17, the other end of a third spring 30 is welded with the positioning carrying end block 19, two sides of the bottom end of the positioning carrying end block 19 are welded with a clamping stroke block 20, two ends of the bottom end of the clamping stroke block 20 are in sliding connection with locking clamping blocks 21, the bottom end of a multi-directional stable support frame 14 is welded with a mounting stable support frame 22, the bottom end of the multi-directional stable support frame 14 is also welded with an inner carrying shell 28, the two inner carrying shells 28 are respectively positioned on two sides of the mounting stable support frame 22, the inside of the mounting stable support frame 22 is in sliding connection with a pressure-bearing sliding plate 25, the inside of the pressure bearing sliding plate 25 is welded with a stress push rod 24, the top end of the stress push rod 24 is attached to a first spring 26, and the bottom end of the stress push rod 24 is welded with a contact conduction pressing plate 23, separately derive slide bar 27 and weld respectively in the both sides on contact conduction clamp plate 23 top, the one end of contact conduction clamp plate 23 is connected with built-in carrying on shell 28 through second spring 29, is convenient for carry on-vehicle carrying on and supports to accomplish good stability, avoid rocking the influence to monitoring devices.

The scheme has the following working processes:

the clamping width adaptation adjustment of vehicle carrying frames with different widths is completed by pushing the locking clamping block 21 to slide at the clamping stroke block 20, so that the locking clamping block 21 is closed to complete clamping and closing, the vehicle body carries the multidirectional discrete stable supporting structure 31 to complete carrying and supporting, in the process of driving displacement to drive measurement, air in the moving process is pumped and exhausted into the light transmission measuring bin 3 through the guide-in fan 2, laser irradiation is performed through the laser emitting end 7 at the moment, after passing through the first lens frame 8, the laser is amplified and dispersed, the irradiation area is enlarged by utilizing the dispersion, when the laser irradiates dust and dust, ejection of light energy is generated, the ejection irradiates to the photoelectric receiving board 10 after being gathered by the second lens frame 9, photoelectric receiving of the photoelectric receiving board 10 is converted into an optical electrical signal, the optical signal is amplified by the amplifying circuit in the multi-circuit carrying box 11 and then is guided into the microprocessor at the signal processing circuit board 12 for operation, the obtained operation data is led into a GPRS export module 13 through a signal export module, GPRS in the GPRS export module 13 is used for sending data to a cloud server, GPRS represents general packet radio service which is a wireless communication service based on grouping, the GPRS works at a data rate and is arranged in the sky according to a built-in 5G transmission network, so that the connection of the Internet is achieved, in the monitoring process, the GPRS always moves along with a vehicle, when the vehicle shakes indefinitely, corresponding impact is easy to generate to influence a monitoring device, when shaking impact of up-and-down bouncing is generated, impact force is received through the contact of a contact conduction pressing plate 23 and the vehicle roof and is shared through linkage sliding of a stress push rod 24 and a discrete derivation slide rod 27, the shared stress at the stress push rod 24 is weakened through sliding of a pressure bearing sliding plate 25 and then led into a first spring 26, and the stress sliding at the discrete derivation slide rod 27 is transmitted to a second spring 29, the offset of impact force is completed by utilizing the elastic potential energy generated by the stress compression of the first spring 26 and the second spring 29, the stress conduction is reduced, the secondary stabilization is completed by utilizing the air compression of the inflatable spring cushion 15, when the lateral stress is applied, the force unloading sliding block 17 in the stress direction is pushed to complete the sliding displacement inside the adapting stroke limiting block 18 for force unloading through the following stress of the multidirectional stable supporting frame 14, and the limit is completed through the elasticity of the third spring 30, so that the overtravel is avoided.

According to the working process, the following steps are known:

Furthermore, a limiting sliding through hole is formed in the bottom end of the assembling stabilizing support 22, the limiting sliding through hole is in clearance fit with the stressed push rod 24, a force guide rail rod is welded at the top end of the discrete derivation slide rod 27, an assembling push piece is welded at the top end of the force guide rail rod, a component force sliding hole is formed in the bottom end of the built-in carrying shell 28, the component force sliding hole is in clearance fit with the force guide rail rod, the diameter of the assembling push piece is five centimeters, the diameter of the component force sliding hole is three centimeters, and therefore the up-down vibration transmission between the bottoms can be conveniently completed to continue discrete conduction pushing and unloading;

furthermore, a plurality of dovetail sliding blocks are welded on two sides of the pressure-bearing sliding plate 25, dovetail sliding grooves are formed in the inner walls of two sides of the assembled stable bracket 22, the dovetail sliding blocks and the dovetail sliding grooves are in clearance fit, so that the pressure-bearing sliding plate 25 can slide and unload force of shaking impact transmitted by the force-bearing push rod 24 by sliding in the assembled stable bracket 22, and the transmission press-in force is reduced;

furthermore, the inside of the adapting stroke limiting block 18 is provided with a force-unloading sliding push guide groove, two sides of the force-unloading sliding block 17 are welded with adapting bumps, and the adapting bumps and the force-unloading sliding push guide groove are in clearance fit, so that the sliding force unloading of longitudinal and transverse shaking impact stress is conveniently completed;

furthermore, a T-shaped derivation displacement block is welded at the top end of the locking clamping block 21, matching T-shaped chutes are formed in two ends of the lower surface of the clamping stroke block 20, and the matching T-shaped chutes and the T-shaped derivation displacement block are in clearance fit, so that the clamping distance can be conveniently adjusted in a sliding adaptability manner, and the overall carrying clamping adaptability of the multidirectional discrete stable supporting structure 31 carried by the vehicle body is improved;

furthermore, a signal amplification circuit is mounted inside the multi-circuit mounting box 11, the photoelectric receiving board 10 is electrically connected with the signal amplification circuit, the photoelectric receiving board 10 is SD5600/5610, a microprocessor and a signal derivation module are mounted inside the signal processing circuit board 12, the microprocessor, the signal amplification circuit and the signal derivation module are electrically connected, a signal of the microprocessor is a8386DX16, a signal derivation module is SIGA-CC1C, the signal derivation module is electrically connected with the GPRS derivation module 13, and one side of the GPRS derivation module 13 is rotatably connected with a signal diffusion antenna.

The foregoing shows and describes the general principles of the present patent, its essential features, and its advantages. It will be understood by those skilled in the art that the invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention patent claims is defined by the appended claims and their equivalents.

Claims

1. The intelligent atmospheric pollution monitoring equipment based on 5G communication comprises an assembly camera bellows (1) and is characterized in that a guide-in fan (2) is fixed at the top end of the assembly camera bellows (1) through screws, a discharge fan (4) is fixed at the bottom end of the assembly camera bellows (1) through screws, a light transmission measuring bin (3) is clamped between the guide-in fan (2) and the discharge fan (4), two sides of the assembly camera bellows (1) are connected with contact positioning plates (5) through rotating pins, extension carrying rods (6) are welded at the upper end and the lower end of one end of the assembly camera bellows (1), a laser emitting end (7) is fixed between the extension carrying rods (6) and the extension carrying rods (6), a first lens frame (8) is fixed at one end of the laser emitting end (7), a second lens frame (9) is fixed inside the other end of the assembly camera bellows (1), and a photoelectric receiving plate (10) is fixedly connected with the second lens frame (9), the photoelectric receiving plate (10) is positioned at one end of the second lens holder (9), a multi-circuit carrying box (11) is fixed at one end of the photoelectric receiving plate (10), a signal amplifying circuit is arranged in the multi-circuit carrying box (11), the photoelectric receiving board (10) is electrically connected with the signal amplifying circuit, a signal processing circuit board (12) is mounted in the multi-circuit carrying case (11), a microprocessor and a signal derivation module are arranged in the signal processing circuit board (12), the microprocessor is electrically connected with the signal amplifying circuit and the signal deriving module, one end of the multi-circuit carrying box (11) is fixed with a GPRS deriving module (13), the signal derivation module is electrically connected with the GPRS derivation module (13), and one side of the GPRS derivation module (13) is rotatably connected with a signal diffusion antenna;

the bottom end of the contact positioning plate (5) is fixed with a vehicle body carrying multidirectional discrete stable supporting structure (31), the vehicle body carrying multidirectional discrete stable supporting structure (31) comprises a multidirectional stable supporting frame (14), an inflatable spring pad (15), a stable extension carrying block (16), a force unloading sliding block (17), a matching stroke limiting block (18), a positioning carrying end block (19), a clamping stroke block (20), a locking clamping block (21), a matching stable support (22), a contact conduction pressing plate (23), a stress push rod (24), a pressure bearing sliding plate (25), a first spring (26), a derivation sliding rod (27), an internal carrying shell (28), a second spring (29) and a third spring (30), the top end of the multidirectional stable supporting frame (14) is fixedly connected with the inflatable spring pad (15) through screws, four ends of the multidirectional stable supporting frame (14) are welded with the stable extension carrying block (16), the top of one end of the stable extension carrying block (16) is welded with the force unloading sliding block (17), the bottom of one end of the stable extension carrying block (16) is welded with the third spring (30), one end of the positioning carrying end block (19) is welded with the matching stroke limiting block (18), the matching stroke limiting block (18) is connected with the force unloading sliding block (17) in a sliding manner, the other end of the third spring (30) is welded with the positioning carrying end block (19), two sides of the bottom end of the positioning carrying end block (19) are welded with the clamping stroke block (20), two ends of the bottom end of the clamping stroke block (20) are connected with the locking clamping blocks (21) in a sliding manner, the bottom end of the multidirectional stable support frame (14) is welded with the stable support frame (22), and the bottom end of the multidirectional stable support frame (14) is also welded with the built-in carrying shell (28), the two built-in carrying shells (28) are respectively positioned at two sides of a mounting stabilizing support (22), the inside of the mounting stabilizing support (22) is in sliding connection with a pressure-bearing sliding plate (25), the inside of the pressure-bearing sliding plate (25) is in welding connection with a stress push rod (24), the top end of the stress push rod (24) is attached to a first spring (26), the bottom end of the stress push rod (24) is in welding connection with a contact conducting pressing plate (23), a discrete derivation sliding rod (27) is respectively welded at two sides of the top end of the contact conducting pressing plate (23), and one end of the contact conducting pressing plate (23) is connected with the built-in carrying shells (28) through a second spring (29).

2. The intelligent atmospheric pollution monitoring device based on 5G communication as claimed in claim 1, wherein the inside of the bottom end of the assembled stabilizing support (22) is provided with a limiting sliding through hole, and the limiting sliding through hole is in clearance fit with the stressed push rod (24).

3. The intelligent atmospheric pollution monitoring device based on 5G communication of claim 1, wherein a plurality of dovetail sliding blocks are welded on both sides of the pressure-bearing sliding plate (25), dovetail sliding grooves are formed in inner walls of both sides of the assembling stabilizing support (22), and the dovetail sliding blocks and the dovetail sliding grooves are in clearance fit.

4. The atmospheric pollution intelligent monitoring equipment based on 5G communication as claimed in claim 1, wherein the inside of the adapting stroke limiting block (18) is provided with a force-unloading sliding pushing guide groove, two sides of the force-unloading sliding block (17) are welded with adapting convex blocks, and the adapting convex blocks and the force-unloading sliding pushing guide groove are in clearance fit.

5. The intelligent atmospheric pollution monitoring device based on 5G communication as claimed in claim 1, wherein a T-shaped derivation displacement block is welded at the top end of the locking clamping block (21), matching T-shaped sliding grooves are formed in both ends of the lower surface of the clamping stroke block (20), and the matching T-shaped sliding grooves and the T-shaped derivation displacement block are in clearance fit.

6. The atmospheric pollution intelligent monitoring equipment based on 5G communication is characterized in that a force guide rail rod is welded at the top end of the discrete derivation sliding rod (27), an adaptive push piece is welded at the top end of the force guide rail rod, a component force sliding hole is formed in the bottom end of the built-in carrying shell (28), the component force sliding hole and the force guide rail rod are in clearance fit, the diameter of the adaptive push piece is five centimeters, and the diameter of the component force sliding hole is three centimeters.

7. An intelligent atmospheric pollution monitoring device based on 5G communication as claimed in claim 1, wherein the model of the photoelectric receiving board (10) is SD 5600/5610.

8. The intelligent atmospheric pollution monitoring device based on 5G communication as claimed in claim 7, wherein the signal of the microprocessor is A8386DX16, and the model of the signal derivation module is SIGA-CC 1C.