CN117098366A - Sensor data acquisition device based on wireless communication and use method - Google Patents

Abstract

The application discloses a wireless communication sensor based data acquisition device and a using method thereof, in particular to the field of wireless communication sensor data acquisition devices, comprising the following steps: the device comprises a device shell, wherein a data acquisition module is arranged in the device shell, a heat dissipation mechanism used for dissipating heat of the data acquisition module is arranged in the device shell, a fixing mechanism used for disassembling and assembling the data acquisition module is arranged above the data acquisition module in the device shell, and a bottom plate is fixedly connected to the bottom of the device shell, so that the device has the technical effects and advantages that: the heat dissipation mechanism is arranged to facilitate the improvement of the heat dissipation effect of the device, and meanwhile, dust stained on the first dust screen and the second dust screen is conveniently cleaned, so that the phenomenon of blockage of the dust is avoided, and the normal heat dissipation of the device is influenced; the fixing mechanism is convenient for automatically locking or disassembling the data acquisition module when the access door is opened and closed, so that convenience in overhaul of the data acquisition module is improved, and the complicated degree of work is reduced.

Description

Sensor data acquisition device based on wireless communication and use method

Technical Field

The application relates to the technical field of wireless communication sensor data acquisition devices, in particular to a wireless communication sensor data acquisition device and a using method thereof.

Background

The wireless communication sensor is a detection device, can sense the measured information, and can convert the sensed information into an electric signal or other information output in a required form according to a certain rule so as to meet the requirements of information transmission, processing, storage, display, recording, control and the like. The method is characterized by comprising the following steps: microminiaturization, digitization, intellectualization, multifunction, systemization, networking. The method is a primary link for realizing automatic detection and automatic control. The data acquisition is an information sensing technology based on technologies such as the Internet of things, RFID, a global positioning system and infrared induction, and the data acquired by the wireless communication sensor is required to be acquired by a data acquisition device.

When the wireless communication sensor data acquisition device is used, a large amount of heat can be generated when internal components of the wireless communication sensor data acquisition device work, the existing wireless communication sensor data acquisition device can radiate heat through arranging a radiating hole on the side wall of the device and installing a fan, dust is prevented from being blown out of the device through arranging a dust screen, but the arrangement of the dust screen can lead to the acceleration of the air flow rate inside the device and outside, dust on the surface of the dust screen is accumulated and aggravated, a blocking phenomenon is easily caused, the blocking phenomenon is inconvenient to find in time, the internal temperature of the device cannot be timely dissipated easily, the device is damaged, the service life of the device is influenced, the existing wireless communication sensor data acquisition device is provided with an internal data acquisition module which is arranged inside the device in a bolt-fixing mode, when the data acquisition module is required to be overhauled, the shell of the device is required to be disassembled firstly, then the data acquisition module is disassembled from the device, the complicated degree of overhauling is greatly increased, and the working efficiency is greatly reduced.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, an embodiment of the present application provides a wireless communication sensor-based data acquisition device and a method for using the same, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present application provides the following technical solutions: comprising the following steps: the device comprises a device shell, a data acquisition module is arranged in the device shell, a heat dissipation mechanism used for dissipating heat of the data acquisition module is arranged in the device shell, a fixing mechanism used for disassembling and assembling the data acquisition module is arranged above the data acquisition module in the device shell, and a bottom plate is fixedly connected to the bottom of the device shell.

In a preferred embodiment, the heat dissipation mechanism comprises a heat conduction copper sheet horizontally and fixedly connected in a device shell, the data acquisition module is placed on the surface of the heat conduction copper sheet, the heat conduction copper sheet is of a folding structure, the bottom surface of the heat conduction copper sheet is vertically and fixedly connected with a plurality of heat dissipation fins, the heat dissipation fins are divided into two rows in a straight line and are positioned on two sides below the heat conduction copper sheet, the bottoms of the two sides of the device shell are positioned on two sides below the heat conduction copper sheet and are respectively provided with a flow guide opening in a penetrating way, the bottom of the device shell is positioned on one side of one flow guide opening and is provided with a heat dissipation fan, the two sides of the device shell are respectively provided with a plurality of heat dissipation openings in a penetrating way in an inclined way above the heat conduction copper sheet, the middle end of the bottom of the heat conduction copper sheet is fixedly connected with a mounting frame, a winding wheel is rotationally connected on the mounting frame, the two sides of the mounting frame are respectively rotationally connected with impellers, the device comprises an impeller, a rolling wheel, a speed reducer, a heat conducting copper sheet, a first guide wheel, a second guide wheel, a first guide wheel, a second guide wheel and a third guide wheel.

In a preferred embodiment, two dustproof nets are all installed in the guide opening, the drive bin is all seted up at the top in the guide opening, drive bin one side runs through device casing inside wall, be connected with the rotor plate through the axostylus axostyle rotation in the drive bin, rotor plate one end bottom is connected with the transfer pole through the changeover piece rotation, the rotor plate other end stretches into in the device casing and is located corresponding dustproof net below, be located dustproof net one side No. two in the guide opening and be equipped with the clearance frame, transfer pole keeps away from rotor plate one end and rotates with clearance frame top through the changeover piece and be connected, clearance frame both sides all with guide opening inside wall sliding connection, the brush hair is all installed to clearance frame be close to No. two dustproof net one side tops and bottom, brush hair and No. two dustproof net lateral wall contact connection.

In a preferred embodiment, dust guiding inclined planes are respectively formed on one side of the second dust screen at the inner top of the two guide openings.

In a preferred embodiment, the data acquisition module includes a power supply module, a data acquisition device, a USB storage module and a G communication module mounted on the top surface thereof, and the data acquisition module is electrically connected to the power supply module, the data acquisition device, the USB storage module and the G communication module.

In a preferred embodiment, the fixed establishment is including locating the installing frame of data acquisition module top, the equal fixedly connected with diaphragm of installing frame middle-end level, the equal fixedly connected with compression spring in diaphragm top surface both ends, compression spring top and device casing interior top fixed connection, be equipped with the gag lever post in the compression spring, gag lever post top and device casing interior top fixed connection, the gag lever post bottom runs through diaphragm lateral wall and diaphragm sliding connection, the equal vertical fixedly connected with location depression bar in installing frame bottom four corners department, four the location depression bar bottom respectively with data acquisition module top surface four corners department contact connection.

In a preferred embodiment, the front side of the device shell is rotationally connected with an access door through a hinge, two ends of the access door, which are close to the bottom of one side of the data acquisition module, are horizontally and fixedly connected with ejector rods, two side walls of the positioning compression rods on the same side are horizontally and fixedly connected with guide rods at opposite positions of the ejector rods, sliding grooves are formed in the bottoms of the guide rods, and one ends, which are far away from the access door, of the ejector rods are slidably connected with the corresponding sliding grooves.

In a preferred implementation mode, device casing front side is located the equal fixedly connected with supporting shoe in access door bottom both ends, supporting shoe top surface and access door side contact are connected, device casing front side is located access door one side fixedly connected with fixed block, the fixed block is close to access door one side and has seted up the storage tank, sliding connection has spacing kelly in the storage tank, spacing kelly one end fixedly connected with compression spring No. two, no. two compression spring is kept away from spacing kelly one end and is accomodate groove inside wall fixed connection, no. two compression spring one end tops are kept away from to spacing kelly are fixed with the arc piece, arc piece and spacing kelly are integrated into one piece structure, arc piece surface and access door side wall sliding connection, the drive mouth has been seted up to storage tank one side run through the fixed block lateral wall, spacing kelly one side fixedly connected with actuating lever, actuating lever one end runs through the drive mouth and stretches to fixed block one side, actuating lever lateral wall and drive mouth inside wall sliding connection.

In a preferred embodiment, S1 is included: when the device works, the power supply module on the data acquisition module supplies power to the data acquisition module, the data acquisition device on the power supply module acquires and records data information transmitted by the wireless communication sensor, a worker can download the acquired data through the USB storage module, and the acquired data can be uploaded to the Internet through the G communication module;

s2: in operation, the heat conducting copper sheet is convenient for absorbing heat generated by the operation of the data acquisition module, the heat conducting copper sheet is guided to the radiating fin, the heat conducting copper sheet works through the radiating fan, the circulation speed of air below the heat conducting copper sheet is conveniently accelerated, the heat absorbed on the radiating fin is discharged out of the device along with the circulation of the air, the heat dissipation of the device is realized, the strong wind blown by the radiating fan is convenient for driving the two impellers to rotate, the two impellers are convenient for driving the winding wheel to rotate through the speed reducer, the winding wheel rotates and winds the rope, the rope winds and pulls the first dust screen to move to the highest position, when the device does not work, the radiating fan stops working, the impeller is not influenced by wind force, the first dust screen slides downwards under the influence of self gravity, the side wall of the impeller scrapes the radiating opening, dust stained on the surface of the first dust screen is scraped, and then the dust is discharged through the inclined radiating opening;

s3: the first dust screen slides downwards and simultaneously presses the rotating plate to rotate, the rotating plate can pull the cleaning frame to move upwards through the transfer rod while rotating, bristles arranged on the cleaning frame can scrape the surface of the second dust screen while the cleaning frame moves, dust stained on the cleaning frame is brushed off, and the brushed dust is discharged through the dust guiding inclined plane;

s4: when the data acquisition module is required to be disassembled and overhauled, the access door is rotated to be in a horizontal state, the access door is supported to be in the horizontal state through the two supporting blocks, the side wall of the access door can push the arc-shaped block to be contracted into the storage groove when rotating, the access door can drive the two ejector rods to rotate when rotating, the two ejector rods slide in the two sliding grooves respectively, the ejector rods can push the guide rods and drive the mounting frame to move upwards when sliding in the sliding grooves, the four positioning compression rods are separated from the data acquisition module, the first compression spring is in a compression state, the arc-shaped block is simultaneously ejected out of the storage groove through the elasticity of the second compression spring, the position of the access door is limited, then the data acquisition module can be taken out of the device shell to be overhauled, the data acquisition module can be supported through the access door which is horizontally arranged, after overhauling is completed, the data acquisition module is placed at the appointed position on the heat conducting copper sheet, then the driving rod is pulled to drive the arc-shaped block to be stored into the storage groove, and then the door is closed, and the mounting frame is driven to move the positioning compression rod downwards through the elasticity of the first compression spring to press and fix the data acquisition module.

The application has the technical effects and advantages that:

1. the heat dissipation mechanism is arranged to facilitate the improvement of the heat dissipation effect of the device, and meanwhile, dust stained on the first dust screen and the second dust screen is conveniently cleaned, so that the phenomenon of blockage of the dust is avoided, and the normal heat dissipation of the device is influenced;

2. the fixing mechanism is convenient for automatically locking or disassembling the data acquisition module when the access door is opened and closed, so that convenience in overhaul of the data acquisition module is improved, and the complicated degree of work is reduced.

Drawings

FIG. 1 is a schematic view of the front cut-away structure of the present application.

Fig. 2 is a schematic diagram of a front view structure of the present application.

Fig. 3 is a schematic view of a first dust-proof net connection structure according to the present application.

Fig. 4 is a schematic view of a connection structure of a rotating plate according to the present application.

Fig. 5 is a schematic view of the structure of the heat conductive copper sheet according to the present application.

Fig. 6 is a schematic view of the impeller connection structure of the present application.

Fig. 7 is a schematic diagram of a connection structure of a positioning compression bar according to the present application.

Fig. 8 is a schematic view showing a cut-away structure of a fixing block according to the present application.

Fig. 9 is a schematic view of a connection structure of a limiting clip rod according to the present application.

The reference numerals are: 1. a device housing; 2. a data acquisition module; 3. a heat dissipation mechanism; 4. a fixing mechanism; 5. a bottom plate; 6. a thermally conductive copper sheet; 7. a heat sink; 8. a diversion port; 9. a heat radiation fan; 10. a heat radiation port; 11. a mounting frame; 12. a winding wheel; 13. an impeller; 14. a first guide wheel; 15. a rope; 16. a second guide wheel; 17. a first dust screen; 18. a U-shaped limiting plate; 19. a driving bin; 20. cleaning a frame; 21. brushing; 22. a second dust screen; 23. a transfer rod; 24. a rotating plate; 25. a mounting frame; 26. a first compression spring; 27. a limit rod; 28. a cross plate; 29. positioning a compression bar; 30. an access door; 31. a push rod; 32. a guide rod; 33. a chute; 34. a fixed block; 35. a storage groove; 36. a limit clamping rod; 37. an arc-shaped block; 38. a compression spring II; 39. a driving port; 40. a driving rod; 41. dust guiding inclined plane; 42. and a supporting block.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

A wireless communication sensor-based data acquisition device as shown in figures 1-9, comprising: the device comprises a device shell 1, a data acquisition module 2 is arranged in the device shell 1, a heat dissipation mechanism 3 used for dissipating heat of the data acquisition module 2 is arranged in the device shell 1, a fixing mechanism 4 used for disassembling and assembling the data acquisition module 2 is arranged above the data acquisition module 2 in the device shell 1, and a bottom plate 5 is fixedly connected to the bottom of the device shell 1.

The heat dissipation mechanism 3 comprises a heat conduction copper sheet 6 horizontally and fixedly connected in the device shell 1, the data acquisition module 2 is placed on the surface of the heat conduction copper sheet 6, the heat conduction copper sheet 6 is of a folding structure, a plurality of heat dissipation fins 7 are vertically and fixedly connected to the bottom surface of the heat conduction copper sheet 6, the heat dissipation fins 7 are linearly divided into two rows and are positioned at two sides below the heat conduction copper sheet 6, two flow guide ports 8 are penetrated and arranged at the bottoms of the two sides of the device shell 1 and positioned below the heat conduction copper sheet 6, the heat dissipation fan 9 is arranged at one side of one flow guide port 8 at the inner bottom of the device shell 1, a plurality of heat dissipation ports 10 are obliquely penetrated and arranged at the two sides of the device shell 1 and positioned above the heat conduction copper sheet 6, the mounting frame 11 is fixedly connected to the middle end of the bottom of the heat conduction copper sheet 6, the winding wheel 12 is rotatably connected to the mounting frame 11, two impellers 13 are rotatably connected to the two sides of the mounting frame 11, the two impellers 13 are fixedly connected with the winding wheel 12 through a speed reducer, the two ropes 15 are fixedly connected with the winding wheel 12, the first dust screen 17 is fixedly connected at the opposite positions of the heat dissipation openings 10 on the two sides of the inner side wall of the device shell 1, the U-shaped limiting plate 18 is fixedly connected below the first dust screen 17, the side wall of the first dust screen 17 is fixedly connected with the inner side wall of the U-shaped limiting plate 18, the two second guide wheels 16 are erected on the inner top of the device shell 1 and respectively positioned above the two first dust screens 17, the two first guide wheels 14 are erected on the bottom surface of the heat conducting copper sheet 6 and are positioned at the two ends of the mounting frame 11, one end of the two first guide wheels 14, which is far away from the winding wheel 12, respectively passes through the corresponding first guide wheels 14 and the side wall of the heat conducting copper sheet 6 and the second guide wheels 16 and is fixedly connected with the top of the corresponding first dust screen 17, the rope 15 is in rolling connection with the corresponding first guide wheel 14 and second guide wheel 16.

Two No. two dust screens 22 are installed respectively in two water conservancy diversion mouths 8, drive storehouse 19 is offered at the interior top of water conservancy diversion mouth 8, drive storehouse 19 one side runs through device casing 1 inside wall, rotating plate 24 passes through the axostylus axostyle rotation and connects in drive storehouse 19, adapter rod 23 one end is rotated through the changeover piece and is connected in rotating plate 24 one end bottom, the rotating plate 24 other end stretches into device casing 1 and is located corresponding No. one dust screen 17 below, cleaning frame 20 locates in water conservancy diversion mouth 8 and is located No. two dust screens 22 one side, the adapter rod 23 other end passes through the changeover piece and is connected with cleaning frame 20 top rotation, cleaning frame 20 both sides all with water conservancy diversion mouth 8 inside wall sliding connection, cleaning frame 20 is close to No. two dust screens 22 one side top and bottom and all installs brush hair 21, brush hair 21 and No. two dust screen 22 lateral wall contact connection.

The top in the two diversion openings 8 is positioned at one side of the second dust screen 22 and is provided with a dust guiding inclined plane 41.

The data acquisition module 2 comprises a power supply module, a data acquisition device, a USB storage module and a 5G communication module which are arranged on the top surface of the data acquisition module 2, and the data acquisition module 2 is electrically connected with the power supply module, the data acquisition device, the USB storage module and the 5G communication module.

The fixed establishment 4 is including locating the installing frame 25 of data acquisition module 2 top, diaphragm 28 level fixed connection is in installing frame 25 middle-end, two compression spring 26 fixed connection are in diaphragm 28 top surface both ends, compression spring 26 top and device casing 1 interior top fixed connection, gag lever post 27 is located in compression spring 26, gag lever post 27 top and device casing 1 interior top fixed connection, gag lever post 27 bottom runs through diaphragm 28 lateral wall and diaphragm 28 sliding connection, four vertical fixed connection of location depression bar 29 are in installing frame 25 bottom four corners department, four location depression bar 29 bottom respectively with data acquisition module 2 top surface four corners department contact connection.

The front side of the device shell 1 is rotationally connected with an access door 30 through a hinge, two ejector rods 31 are horizontally and fixedly connected with two ends of the bottom of one side of the access door 30, which is close to the data acquisition module 2, two positioning compression rods 29 on the same side are respectively and fixedly connected with a guide rod 32 in a manner that the side walls of the two positioning compression rods 29 are positioned at the opposite positions of the ejector rods 31, a chute 33 is formed in the bottom of the guide rod 32, and one end, which is far away from the access door 30, of the ejector rods 31 is in sliding connection with the corresponding chute 33.

Two supporting blocks 42 are fixedly connected to the front side of the device shell 1 and are located at two ends of the bottom of the access door 30, the top surface of each supporting block 42 is in contact connection with the side surface of the access door 30, the fixed block 34 is fixedly connected to the front side of the device shell 1 and located on one side of the access door 30, the storage groove 35 is formed in one side, close to the access door 30, of the fixed block 34, the limiting clamping rod 36 is slidably connected to the storage groove 35, the second compression spring 38 is fixedly connected to one end, away from the limiting clamping rod 36, of the second compression spring 38, the arc-shaped block 37 is fixedly connected to the top of one end, away from the second compression spring 38, of the limiting clamping rod 36, the arc-shaped block 37 and the limiting clamping rod 36 are integrally formed, the surface of the arc-shaped block 37 is slidably connected to the side wall of the access door 30, the driving opening 39 penetrates through the side wall of the fixed block 34 on one side of the storage groove 35, the driving rod 40 is fixedly connected to one side of the limiting clamping rod 36, one end of the driving rod 40 penetrates the driving opening 39 to one side of the fixed block 34, and the side of the driving rod 40 is slidably connected to the inner wall of the driving rod 40.

The implementation mode specifically comprises the following steps: the heat dissipation mechanism 3 is arranged to facilitate the improvement of the heat dissipation effect of the device, and meanwhile, the dust stained on the first dust screen 17 and the second dust screen 22 is conveniently cleaned, so that the phenomenon of blockage of the dust is avoided, and the normal heat dissipation of the device is influenced; the fixing mechanism 4 is convenient for automatically locking or disassembling the data acquisition module 2 when the access door 30 is opened and closed, so that convenience in overhaul of the data acquisition module is improved, and the complicated degree of work is reduced.

A method for using a wireless communication sensor-based data acquisition device as shown in fig. 1-9, comprising S1: when the device works, the power supply module on the data acquisition module 2 supplies power to the data acquisition module 2, the data acquisition device on the power supply module acquires and records data information transmitted by the wireless communication sensor, a worker can download the acquired data through the USB storage module, and the acquired data can be uploaded to the Internet through the 5G communication module;

s2: in operation, the heat conducting copper sheet 6 is convenient for absorbing heat generated by the operation of the data acquisition module 2 and guiding the heat conducting copper sheet to the radiating fin 7, the heat conducting copper sheet is operated through the radiating fan 9, and the two flow guide ports 8 are matched, so that the circulation speed of air below the heat conducting copper sheet 6 is conveniently accelerated, the heat absorbed on the radiating fin 7 is discharged out of the device along with the circulation of the air, the heat dissipation of the device is realized, the strong wind blown by the radiating fan 9 is convenient for driving the two impellers 13 to rotate, the two impellers 13 are convenient for driving the winding wheel 12 to rotate through the speed reducer, the winding wheel 12 rotates and winds the rope 15, the rope 15 winds and pulls the first dust screen 17 to move to the highest position, when the device does not operate, the radiating fan 9 stops operating, the impellers 13 are not influenced by wind, the first dust screen 17 slides downwards under the influence of gravity of the self, the side wall of the impeller is scraped with the radiating port 10, dust stained on the surface of the first dust screen 17 is scraped, and is discharged through the obliquely arranged radiating port 10;

s3: the first dust screen 17 slides downwards and simultaneously presses the rotating plate 24 to rotate, the rotating plate 24 rotates and simultaneously pulls the cleaning frame 20 to move upwards through the switching rod 23, the bristles 21 arranged on the cleaning frame 20 can scrape the surface of the second dust screen 22 while moving, dust stained on the cleaning frame is brushed off, and the brushed dust is discharged through the dust guiding inclined plane 41;

s4: when the data acquisition module 2 needs to be disassembled and overhauled, the access door 30 is rotated to be in a horizontal state, the access door 30 in the horizontal state is supported by the two supporting blocks 42, the side wall of the access door 30 can push the arc-shaped blocks 37 to retract into the accommodating groove 35 while rotating, the access door 30 can drive the two ejector rods 31 to rotate while rotating, the two ejector rods 31 slide in the two sliding grooves 33 respectively, the ejector rods 31 can push the guide rods 32 and drive the mounting frame 25 to move upwards when sliding in the sliding grooves 33, the four positioning compression rods 29 are separated from the data acquisition module 2, the first compression spring 26 is in a compressed state at the moment, the arc-shaped blocks 37 are simultaneously ejected from the accommodating groove 35 by the elastic force of the second compression spring 38, the position of the access door 30 is limited, then the data acquisition module 2 can be taken out from the device shell 1 to be overhauled, the horizontally arranged access door 30 can be supported, after the overhauling is completed, the data acquisition module 2 is placed at the appointed position on the heat conducting copper sheet 6, the arc-shaped sheet 37 is driven to be accommodated in the accommodating groove 35 by the driving rod 40, then the first compression spring 26 is driven to be pushed down, and the first compression spring 26 is driven to move downwards by the first compression spring 26 to press the first compression spring 29, and the first compression spring 29 is fixed.

The last points to be described are: first, in the description of the present application, it should be noted that, unless otherwise specified and defined, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be mechanical or electrical, or may be a direct connection between two elements, and "upper," "lower," "left," "right," etc. are merely used to indicate relative positional relationships, which may be changed when the absolute position of the object being described is changed;

secondly: in the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, and other structures can refer to the common design, so that the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict;

finally: the foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the application are intended to be included within the scope of the application.

Claims (9)

1. A wireless communication sensor-based data acquisition device, comprising: device housing (1), characterized in that: be equipped with data acquisition module (2) in device casing (1), be equipped with in device casing (1) and be used for carrying out radiating heat dissipation mechanism (3) to data acquisition module (2), be located data acquisition module (2) top in device casing (1) and be equipped with fixed establishment (4) that are used for carrying out dismouting to data acquisition module (2), device casing (1) bottom fixedly connected with bottom plate (5).

2. The wireless communication sensor-based data acquisition device of claim 1, wherein: the heat dissipation mechanism (3) comprises a heat conduction copper sheet (6) horizontally and fixedly connected in a device shell (1), the data acquisition module (2) is placed on the surface of the heat conduction copper sheet (6), the heat conduction copper sheet (6) is of a folding structure, a plurality of heat dissipation fins (7) are vertically and fixedly connected to the bottom surface of the heat conduction copper sheet (6), the heat dissipation fins (7) are linearly divided into two rows and are positioned at two sides below the heat conduction copper sheet (6), the bottoms of the two sides of the device shell (1) are positioned at two sides of the heat conduction copper sheet (6) and are respectively penetrated by a heat conduction mouth (8), a heat dissipation fan (9) is installed at one side of the heat conduction mouth (8) at the inner bottom part of the device shell (1), a plurality of heat dissipation ports (10) are respectively and obliquely penetrated by the two sides of the device shell (1), a plurality of mounting frames (11) are fixedly connected to the middle ends of the bottoms of the heat conduction copper sheet (6), rolling wheels (12) are rotatably connected to the mounting frames (11), impellers (13) are respectively and rotatably connected to the two rolling wheels (13) through the rolling wheels (12) and the rolling wheels (15), the device comprises a device shell (1), wherein the relative positions of radiating ports (10) on two sides of the inner side wall of the device shell are respectively and slidably connected with a first dust screen (17), U-shaped limiting plates (18) are respectively and fixedly connected with the lower parts of the first dust screen (17), the side walls of the first dust screen (17) are respectively and slidably connected with the inner side walls of the U-shaped limiting plates (18), second guide wheels (16) are respectively and fixedly arranged above the two first dust screens (17) on the top of the device shell (1), first guide wheels (14) are respectively and fixedly arranged on the bottom surface of each heat conducting copper sheet (6) on two ends of a mounting frame (11), the two first guide wheels (14) are far away from one end of each winding wheel (12) and respectively pass through the corresponding first guide wheels (14) and the side walls of each second guide wheel (16) to be fixedly connected with the tops of the corresponding first dust screen (17), and ropes (15) are respectively connected with the corresponding first guide wheels (14) and the second guide wheels (16) in a rolling mode.

3. The wireless communication sensor-based data acquisition device of claim 2, wherein: two dustproof nets (22) are all installed in the water conservancy diversion mouth (8), drive storehouse (19) have all been seted up at roof in water conservancy diversion mouth (8), drive storehouse (19) one side runs through device casing (1) inside wall, be connected with rotor plate (24) through the axostylus axostyle rotation in drive storehouse (19), rotor plate (24) one end bottom is connected with transfer pole (23) through the changeover piece rotation, rotor plate (24) other end stretches into device casing (1) in be located corresponding dustproof net (17) below, be located dustproof net (22) one side in water conservancy diversion mouth (8) and be equipped with clearance frame (20), transfer pole (23) are kept away from rotor plate (24) one end and are passed through the changeover piece and are rotated at clearance frame (20) top, clearance frame (20) both sides all are connected with water conservancy diversion mouth (8) inside wall sliding connection, clearance frame (20) are close to dustproof net (22) one side top and bottom and all install brush hair (21), brush hair (21) are connected with dustproof net (22) side wall contact.

4. A wireless communication sensor-based data acquisition device according to claim 3, wherein: dust guiding inclined planes (41) are respectively arranged at one sides of the second dust screen (22) at the inner top parts of the two guide openings (8).

5. The wireless communication sensor-based data acquisition device of claim 1, wherein: the data acquisition module (2) comprises a power supply module, a data acquisition device, a USB storage module and a 5G communication module which are arranged on the top surface of the data acquisition module (2), and the data acquisition module (2) is electrically connected with the power supply module, the data acquisition device, the USB storage module and the 5G communication module.

6. The wireless communication sensor-based data acquisition device of claim 1, wherein: the utility model provides a data acquisition module, including locating mounting frame (25) of data acquisition module (2) top, mounting frame (25) middle-end level fixedly connected with diaphragm (28), equal fixedly connected with compression spring (26) in diaphragm (28) top surface both ends, compression spring (26) top and device casing (1) interior top fixed connection, be equipped with gag lever post (27) in compression spring (26), gag lever post (27) top and device casing (1) interior top fixed connection, gag lever post (27) bottom runs through diaphragm (28) lateral wall and diaphragm (28) sliding connection, all vertical fixedly connected with location depression bar (29) in mounting frame (25) bottom four location depression bar (29) bottom respectively with data acquisition module (2) top surface four corners department contact connection.

7. The wireless communication sensor-based data acquisition device of claim 6, wherein: the device is characterized in that an access door (30) is rotatably connected to the front side of the device shell (1) through a hinge, an ejector rod (31) is fixedly connected to two ends of the bottom of one side of the access door (30) close to the data acquisition module (2) horizontally, two side walls of the positioning compression rods (29) are fixedly connected with guide rods (32) horizontally and at the opposite positions of the ejector rod (31), sliding grooves (33) are formed in the bottoms of the guide rods (32), and one ends of the ejector rods (31) away from the access door (30) are slidably connected with the corresponding sliding grooves (33).

8. The wireless communication sensor-based data acquisition device of claim 1, wherein: the front side of the device shell (1) is positioned at two ends of the bottom of the access door (30) and fixedly connected with a supporting block (42), the top surface of the supporting block (42) is in contact connection with the side surface of the access door (30), one side of the device shell (1) is fixedly connected with a fixed block (34), a storage groove (35) is formed in one side of the fixed block (34) close to the access door (30), a limit clamping rod (36) is connected in the storage groove (35), one end of the limit clamping rod (36) is fixedly connected with a second compression spring (38), one end of the second compression spring (38) far away from the limit clamping rod (36) is fixedly connected with the inner side wall of the storage groove (35), one end top of the limit clamping rod (36) far away from the second compression spring (38) is fixedly connected with an arc-shaped block (37), the arc-shaped block (37) and the limit clamping rod (36) are of an integral structure, the surface of the arc-shaped block (37) is in sliding connection with the side wall of the access door (30), one side wall of the storage groove (35) is internally provided with a limit clamping rod (36), one side wall of the fixed block (34) is internally provided with a limit clamping rod (39), one side of the limit clamping rod (40) is fixedly connected with a drive port (40), one side of the drive rod (40) extends to the drive port (40), the side wall of the driving rod (40) is in sliding connection with the inner side wall of the driving opening (39).

9. A method of using a wireless communication sensor based data acquisition device according to any one of claims 1-8, wherein: comprising S1: when the device works, the power supply module on the data acquisition module (2) supplies power to the data acquisition module (2), the data acquisition device on the power supply module acquires and records data information transmitted by the wireless communication sensor, a worker can download the acquired data through the USB storage module, and the acquired data can be uploaded to the Internet through the 5G communication module;

s2: in operation, the heat conducting copper sheet (6) is convenient for absorbing heat generated by the operation of the data acquisition module (2) and guiding the heat conducting copper sheet to the radiating fin (7), the radiating fan (9) is operated, the two flow guiding ports (8) are matched, the circulation speed of air below the heat conducting copper sheet (6) is convenient to accelerate, the heat absorbed by the radiating fin (7) is discharged out of the device along with the circulation of the air, the heat dissipation of the device is realized, strong wind blown by the radiating fan (9) is convenient for driving the two impellers (13) to rotate, the two impellers (13) are convenient for driving the winding wheel (12) to rotate through the speed reducer, the winding wheel (12) rotates and winds the rope (15), the rope (15) winds and pulls the first dust screen (17) to move to the highest position, when the device does not operate, the first dust screen (17) slides downwards under the influence of gravity of the self, the side wall of the impeller is scraped with the radiating port (10), dust stained on the surface of the first dust screen (17) is scraped off, and then discharged through the inclined radiating port (10);

s3: the first dust screen (17) slides downwards and simultaneously presses the rotating plate (24) to rotate, the rotating plate (24) can pull the cleaning frame (20) to move upwards through the rotating rod (23) while rotating, bristles (21) arranged on the cleaning frame (20) can scrape the surface of the second dust screen (22) while moving, dust stained on the second dust screen is brushed off, and the brushed dust is discharged through the dust guiding inclined plane (41);

s4: when the data acquisition module (2) needs to be disassembled and overhauled, the access door (30) is rotated to be in a horizontal state, the access door (30) in the horizontal state is supported by the two supporting blocks (42), the side wall of the access door (30) can push the arc-shaped block (37) to be contracted into the accommodating groove (35) while rotating, the access door (30) can drive the two ejector rods (31) to rotate while rotating, the two ejector rods (31) respectively slide in the two sliding grooves (33), the ejector rods (31) can push the guide rods (32) and drive the mounting frame (25) to move upwards when sliding in the sliding grooves (33), the four positioning compression rods (29) are separated from the data acquisition module (2), the first compression spring (26) is in a compressed state at the moment, the arc-shaped block (37) is simultaneously ejected from the accommodating groove (35) by the elastic force of the second compression spring (38), then the data acquisition module (2) can be taken out from the device shell (1) to be operated, the data acquisition module (2) can be pulled into the accommodating groove (35) by the horizontally arranged, the data acquisition module (2) can be driven to be accommodated in the accommodating groove (37), then the access door (30) is closed, and at the moment, the mounting frame (25) drives the positioning compression rod (29) to move downwards through the elasticity of the first compression spring (26) so as to press and fix the data acquisition module (2).