CN219248225U - Engineering data acquisition device - Google Patents

Abstract

The application relates to the field of data acquisition, in particular to an engineering data acquisition device, which comprises a shell, a central processing module and a plurality of acquisition modules, wherein the central processing module and the acquisition modules are arranged in the shell, the acquisition modules are used for acquiring data, the shell is provided with a plurality of connecting holes, the acquisition modules are connected with the central processing module through data wires, one ends of the data wires are arranged on the acquisition modules, the other ends of the data wires are provided with plugs, and the plugs can be inserted into the connecting holes; be provided with the shield on the connecting hole, the shield passes through the connecting rope to be connected on the casing, is provided with a plurality of dust rings on the shield, and a plurality of dust rings are arranged along the thickness direction of shield, and this application has the effect that reduces in the dust entering connecting hole.

Description

Engineering data acquisition device

Technical Field

The application relates to the field of data acquisition, in particular to an engineering data acquisition device.

Background

The data acquisition device is used for acquiring data by using a sensor and other detection equipment, the acquired data is sent to an upper computer for analysis and processing, and the data acquisition system is a flexible and user-defined measurement system realized by combining measurement software and hardware products based on a computer or other special test platforms.

The data acquisition device commonly used at present comprises a shell, a central processing module and a plurality of detection devices, wherein the central processing module and the detection devices are arranged in the shell, a plurality of connecting holes are formed in the shell, the detection devices and the processing modules are connected through data wires, plugs are arranged on the wires and are inserted into the connecting holes to be used for connecting the detection devices and the central processing modules, and therefore data in the detection devices are transmitted into the central processing module conveniently.

When the data acquisition device is used, a plurality of detection devices are firstly installed at different positions of a construction site according to the detection data, the data wires are connected to the central processing module, when a plug is not inserted into a connecting hole, the dust on the construction site is large, the number of jacks is large, the jacks are dense, a protective cover plate is arranged integrally, all the jacks are covered simultaneously in the prior art, all the jacks are exposed after the dust cover is opened, only part of the jacks are required to be opened in use, and therefore other inapplicable jacks enter the dust.

Disclosure of Invention

In order to reduce the possibility of dust entering the connecting hole, the application provides an engineering data acquisition device.

The application provides an engineering data acquisition device adopts following technical scheme:

the engineering data acquisition device comprises a shell, a central processing module and a plurality of acquisition modules, wherein the central processing module and the acquisition modules are arranged in the shell, the acquisition modules are used for acquiring data, the shell is provided with a plurality of connecting holes, the acquisition modules are connected with the central processing module through data wires, one ends of the data wires are arranged on the acquisition modules, the other ends of the data wires are provided with plugs, and the plugs can be inserted into the connecting holes; the dustproof cover is connected to the shell through a connecting rope, a plurality of first dustproof rings are arranged on the dustproof cover, and the first dustproof rings are arranged along the thickness direction of the dustproof cover; the plug is provided with a plurality of second dust-proof rings, the second dust-proof rings are arranged along the thickness direction of the plug, and the second dust-proof rings can be inserted into the connecting holes together with the plug.

By adopting the technical scheme, when data are acquired, each acquisition module is firstly installed at a place on a construction site where the data are required to be acquired, and after the acquisition module is installed, the plug is inserted into the connecting hole, because the dust on the construction site is large, when the plug is not inserted into the connecting hole, the dust easily enters the connecting hole, so that the data transmission of the acquisition module can be influenced, and when the plug is not inserted into the connecting hole, the dust cover is covered on the connecting hole, so that the possibility that the dust enters the connecting hole is reduced; before the plug is inserted into the connecting hole, the dustproof cover is opened, and the possibility of losing the dustproof cover is reduced due to the arrangement of the connecting rope. A plurality of dustproof rings are arranged, so that multistage protection is realized, and the dustproof performance is improved.

After the plug is inserted into the connecting hole, a gap may exist between the plug and the connecting hole, dust may be accumulated in the gap, so that data transmission is affected, and therefore, the second dust ring is arranged, and the possibility that dust is accumulated in the gap between the plug and the connecting hole is reduced.

Optionally, a plurality of heat dissipation holes are formed in the shell, and a dustproof structure is arranged on the heat dissipation holes.

By adopting the technical scheme, the central processing module can generate heat when running, the processing efficiency of the central processing module is influenced by overhigh temperature, and the heat dissipation holes are arranged to facilitate heat dissipation; a dustproof structure is arranged on the shell, so that the possibility that dust enters the shell from the radiating holes is reduced.

Optionally, the louvre sets up to follow the casing in to the toper that the casing is outside dwindled gradually, the inside clearance brush that is arranged in of casing is used for sweeping away dust in the louvre, clearance brush along vertical direction sliding connection in the casing.

Through adopting above-mentioned technical scheme, the louvre is the toper setting, and the area that is located the casing inboard is big, and the area that is located the casing outside is little, when carrying out heat dissipation, reduces the possibility that the dust got into the casing. The dust accumulated in the heat dissipation holes can be conveniently swept down by the arrangement of the cleaning brush, and when the dust in the heat dissipation holes is cleaned, the cleaning brush is driven to move, so that the dust accumulated in the heat dissipation holes can be swept down.

Optionally, the dustproof structure includes the dust guard, dust guard sliding connection in on the casing, the casing with be provided with between the dust guard and be used for the drive the gliding drive structure of dust guard.

By adopting the technical scheme, when the central processing module operates, the driving structure drives the dust-proof plate to move, the heat dissipation holes are opened, and when the central processing module stops operating, the driving structure drives the dust-proof plate to move, and the heat dissipation holes are closed; the heat dissipation plate and the driving structure are arranged, so that the heat dissipation holes are opened and closed conveniently.

Optionally, the drive structure includes lead screw, screw nut and is used for the drive the pivoted motor of lead screw, the lead screw rotate connect in on the casing, screw nut threaded connection in on the casing, dust guard fixed connection in on the casing.

By adopting the technical scheme, when the heat dissipation hole is opened, the motor drives the screw rod to rotate, the screw rod nut moves along the length direction of the screw rod, and the dust-proof plate is driven to move, so that the heat dissipation hole is opened; when the heat dissipation hole is closed, the motor drives the screw rod to reversely rotate, the screw rod nut moves along the length direction of the screw rod, the dust-proof plate is driven to reset, and the heat dissipation hole is closed.

Optionally, a cooling fan is arranged inside the shell, and the cooling fan is arranged beside the cooling hole.

By adopting the technical scheme, the radiating fan is arranged, and when the central processing unit heats, the radiating fan is started, so that the radiating efficiency is accelerated.

Optionally, a display screen is arranged on the shell, and a protective film is arranged on the display screen.

Through adopting above-mentioned technical scheme, the setting of display screen is convenient for people observe the detection data, and the possibility that the display screen was scraped to the setting of protection film can be reduced, and the protection film can be changed by scraping to the flower, reduce cost.

Optionally, a plurality of rollers are arranged at the bottom of the shell.

Through adopting above-mentioned technical scheme, after the project finishes, dismantle data acquisition device, transport to next project construction site, the setting of gyro wheel is convenient for remove data acquisition device.

In summary, the present application includes the following beneficial technical effects:

1. through the arrangement of the dustproof cover, the dustproof ring I and the connecting rope, when the plug is not inserted into the connecting hole, the dustproof cover is covered on the connecting hole, so that the possibility that dust enters the connecting hole is reduced; before the plug is inserted into the connecting hole, the dustproof cover is opened, and the connecting rope reduces the possibility of losing the dustproof cover;

2. through the setting of louvre, dust guard and drive structure, when central processing unit is inoperative, drive structure drive dust guard covers the louvre, reduces the possibility that the dust got into in the casing, and at central processing unit during operation, drive structure drive dust guard opens the louvre, the central processing unit of being convenient for dispels the heat.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present application;

FIG. 2 is a schematic structural diagram of an acquisition module according to an embodiment of the present application;

FIG. 3 is a schematic view of the internal structure of the housing according to the embodiment of the present application;

fig. 4 is an enlarged schematic view of the portion a in fig. 2.

Reference numerals illustrate:

1. a housing; 2. a central processing module; 3. an acquisition module; 4. a connection hole; 5. a data line; 6. a plug; 7. a dust cover; 8. a first dust ring; 9. a connecting rope; 10. a dust ring II; 11. a display screen; 12. a protective film; 13. a heat radiation hole; 14. a heat radiation fan; 15. a dust-proof plate; 16. a screw rod; 17. a screw nut; 18. a motor; 19. a fixing plate; 20. a roller; 21. fixing the column; 22. a chute; 23. and (5) cleaning the brush.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment of the application discloses engineering data acquisition device, refer to fig. 1 through 3, including casing 1, set up central processing module 2 and a plurality of collection module 3 that are used for gathering data in casing 1, casing 1 is the cavity setting, in the practical application in-process, collection module 3 sets up to the collection module 3 of different functions according to actual need, gathers the data of each aspect on the construction site, collection module 3 can set up as instruments such as altitude gauge, level gauge.

Referring to fig. 2 and 4, a plurality of connection holes 4 are formed in the housing 1, the acquisition module 3 is connected with the central processing module 2 through a data line 5, one end of the data line 5 is arranged on the acquisition module 3, a plug 6 is arranged at the other end of the data line 5, and the plug 6 can be inserted into the connection holes 4. Be provided with shield 7 on the connecting hole 4, shield 7 passes through connecting rope 9 and connects on casing 1, is provided with a plurality of dust rings 8 on the shield 7, and a plurality of dust rings 8 are arranged along the thickness direction of shield 7. The plug 6 is provided with a plurality of second dust-proof rings 10, the second dust-proof rings 10 are arranged along the thickness direction of the plug 6, and the second dust-proof rings 10 can be inserted into the connecting holes 4 together with the plug 6.

Referring to fig. 1, a display screen 11 is provided on a housing 1, and a protective film 12 is provided on the display screen 11. The housing 1 is provided with a plurality of heat dissipation holes 13, and the heat dissipation holes 13 are tapered so as to gradually decrease from the inside of the housing 1 to the outside of the housing 1. A cooling fan 14 is arranged in the shell 1, and the cooling fan 14 is arranged beside the cooling hole 13. Be provided with dustproof construction on the louvre 13, dustproof construction includes dust guard 15, and dust guard 15 sliding connection is provided with the drive structure that is used for driving dust guard 15 gliding between casing 1 and the dust guard 15 on casing 1. In the embodiment of the present application, the heat dissipation holes 13, the heat dissipation fans 14, and the dust-proof structure are provided in two groups, and the two groups of heat dissipation holes 13, the heat dissipation fans 14, and the dust-proof structure are provided on both sides of the housing 1.

Referring to fig. 1, the driving structure includes a screw 16, a screw nut 17 and a motor 18 for driving the screw 16 to rotate, two fixing plates 19 are fixedly connected to the housing 1, the screw 16 is disposed along the height direction of the housing 1, two ends of the screw 16 are respectively and rotatably connected between the two fixing plates 19, a bearing is disposed between the screw 16 and the fixing plates 19, the motor 18 is fixedly connected to the fixing plates 19, a coupling matched with the screw 16 is disposed on the motor 18, the screw nut 17 is in threaded connection with the housing 1, and the dust-proof plate 15 is fixedly connected to the screw nut 17.

Referring to fig. 3, a cleaning brush 23 for cleaning dust in the heat dissipation holes 13 is disposed inside the housing 1, two fixing columns 21 are fixedly connected in the housing 1, sliding grooves 22 are formed on two opposite sides of the two fixing columns 21, and the cleaning brush 23 is slidably connected in the sliding grooves 22 along the vertical direction. If the dust blocks the heat dissipation holes 13, the cleaning brush 23 is driven to move up and down, so that the dust in the heat dissipation holes 13 can be cleaned down.

Referring to fig. 1, a plurality of rollers 20 are provided at the bottom of the housing 1, and in the embodiment of the present application, four rollers 20 are provided at four corners of the housing 1.

The implementation principle of the engineering data acquisition device in the embodiment of the application is as follows: when data are collected, each collection module 3 is firstly installed at a place where the data are required to be collected on a construction site, and when a plug 6 is not inserted into a connection hole 4, a dust cover 7 is covered on the connection hole 4, so that the possibility that dust enters the connection hole 4 is reduced; before the plug 6 is inserted into the connection hole 4, the dust cover 7 is opened, and the connection rope 9 reduces the possibility of losing the dust cover 7.

When the central processing module 2 operates, the motor 18 drives the screw rod 16 to rotate, the screw rod nut 17 moves along the length direction of the screw rod 16 to drive the dust-proof plate 15 to move, and the heat dissipation hole 13 is opened; when the central processing module 2 stops running, the motor 18 drives the screw rod 16 to reversely rotate, the screw rod nut 17 moves along the length direction of the screw rod 16 to drive the dust-proof plate 15 to reset, and the heat dissipation hole 13 is closed; the heat dissipation plate and the driving structure are arranged, so that the heat dissipation holes 13 are opened and closed conveniently.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. An engineering data acquisition device which is characterized in that: the device comprises a shell (1), a central processing module (2) and a plurality of acquisition modules (3) for acquiring data, wherein the central processing module (2) and the acquisition modules (3) are arranged in the shell (1), a plurality of connecting holes (4) are formed in the shell (1), the acquisition modules (3) are connected with the central processing module (2) through data wires (5), one ends of the data wires (5) are arranged on the acquisition modules (3), plugs (6) are arranged at the other ends of the data wires (5), and the plugs (6) can be inserted into the connecting holes (4); a dust cover (7) is arranged on the connecting hole (4), the dust cover (7) is connected to the shell (1) through a connecting rope (9), a plurality of first dust rings (8) are arranged on the dust cover (7), and the first dust rings (8) are arranged along the thickness direction of the dust cover (7); the plug (6) is provided with a plurality of second dust-proof rings (10), the second dust-proof rings (10) are arranged along the thickness direction of the plug (6), and the second dust-proof rings (10) can be inserted into the connecting holes (4) together with the plug (6).

2. An engineering data acquisition device according to claim 1, wherein: a plurality of radiating holes (13) are formed in the shell (1), and a dustproof structure is arranged on the shell.

3. An engineering data acquisition device according to claim 2, wherein: the cooling hole (13) is arranged into a taper shape which gradually reduces from the inside of the shell (1) to the outside of the shell (1), a cleaning brush (23) for sweeping dust in the cooling hole (13) is arranged inside the shell (1), and the cleaning brush (23) is connected in the shell (1) in a sliding manner along the vertical direction.

4. An engineering data acquisition device according to claim 2, wherein: the dustproof structure comprises a dustproof plate (15), the dustproof plate (15) is connected to the shell (1) in a sliding mode, and a driving structure used for driving the dustproof plate (15) to slide is arranged between the shell (1) and the dustproof plate (15).

5. An engineering data acquisition device according to claim 4, wherein: the driving structure comprises a screw rod (16), a screw rod nut (17) and a motor (18) for driving the screw rod (16) to rotate, wherein the screw rod (16) is rotationally connected to the shell (1), the screw rod nut (17) is in threaded connection with the shell (1), and the dust-proof plate (15) is fixedly connected to the shell (1).

6. An engineering data acquisition device according to claim 3, wherein: a cooling fan (14) is arranged in the shell (1), and the cooling fan (14) is arranged beside the cooling hole (13).

7. An engineering data acquisition device according to claim 1, wherein: a display screen (11) is arranged on the shell (1), and a protective film (12) is arranged on the display screen (11).

8. An engineering data acquisition device according to claim 1, wherein: a plurality of rollers (20) are arranged at the bottom of the shell (1).

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