CN215984634U - Physical data acquisition device - Google Patents

Abstract

The utility model provides a physical data acquisition device, and relates to the technical field of acquisition devices. The physical data acquisition device comprises a device body, wherein a first cavity is formed in the interior close to the rear side of the device body, a heat conduction assembly is arranged at the joint of the first cavity and the interior of the device body, a linkage assembly is accommodated in the first cavity, a motor is mounted at the driving end of the linkage assembly, a cooling assembly is rotatably connected to the linkage assembly, discharge ports are formed in the outer walls of the two sides of the device body, and the discharge ports are communicated with the first cavity; the driving motor drives the cooling component to rotate in the first cavity through the linkage component, and the generated air flow and the heat in the carrying device body are discharged through the discharge port. The physical data acquisition device provided by the utility model has the advantages that the heat conducted out is discharged through the discharge port by the airflow generated when the cooling component rotates, so that the heat dissipation efficiency of the device is improved.

Description

Physical data acquisition device

Technical Field

The utility model relates to the technical field of acquisition devices, in particular to a physical data acquisition device.

Background

Data acquisition refers to automatically acquiring non-electric quantity or electric quantity signals from analog and digital tested units such as sensors and other devices to be tested, and sending the signals to an upper computer for analysis and processing.

But current collection system still has some drawbacks when using, and produced a large amount of heats after the device uses for a long time, can't cool down, discharge a large amount of heats through the heat dissipation merit that device self possessed for not only influence the normal operating of device, also can reduce the life of device simultaneously.

Therefore, there is a need to provide a new physical data acquisition device to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a physical data acquisition device.

The utility model provides a physical data acquisition device which comprises a device body, wherein a first cavity is formed in the interior close to the rear side of the device body, a heat conduction assembly is arranged at the joint of the first cavity and the interior of the device body, a linkage assembly is accommodated in the first cavity, a motor is installed at the driving end of the linkage assembly, a cooling assembly is rotatably connected to the linkage assembly, discharge ports are formed in the outer walls of the two sides of the device body, and the discharge ports are communicated with the first cavity; the driving motor drives the cooling component to rotate in the first cavity through the linkage component, and the generated air flow and the heat in the carrying device body are discharged through the discharge port.

Preferably, the heat conduction assembly comprises a heat conduction plate which is arranged at the joint of the inner part of the device body and the first cavity through a connecting plate, the heat conduction plate is fixedly provided with a plurality of uniformly distributed arrays on the surface of one side of the heat conduction plate, which is far away from the first cavity, and the surface of the heat conduction plate is provided with a plurality of uniformly distributed arrays.

Preferably, the motor is mounted to a rear surface of the device body through a shock-absorbing post.

Preferably, the linkage assembly comprises a driving rotating shaft which is rotatably connected to the driving end of the motor, one end of the driving rotating shaft, which is far away from the motor, extends to the inside of the first cavity, and the tail end of the driving rotating shaft is fixedly sleeved with a driving gear.

Preferably, the upper side and the lower side of the driving gear are respectively connected with a driven gear in a meshing manner, and the inner surfaces of the two driven gears are fixedly provided with driven rotating shafts in a penetrating manner.

Preferably, the cooling assembly comprises a first fixing sleeve fixed on the driving rotating shaft and far away from the tail end of the driving gear, and a plurality of first blades uniformly distributed in a circumferential array are fixed on the outer surface of the first fixing sleeve.

Preferably, the cooling assembly further comprises a second fixing sleeve fixed on the driven rotating shaft and far away from the tail end of the driven gear, and a plurality of second blades uniformly distributed in a circumferential array are fixed on the outer surface of the second fixing sleeve.

Preferably, a second cavity is formed in the inner wall of one side of the device body, a cooling assembly for assisting in cooling the heat inside the device body is accommodated in the second cavity, a cooling tank for storing cooling liquid is installed at the input end of the cooling assembly, and the cooling tank is fixed to the rear side of the device body and is located obliquely below the motor.

Compared with the related art, the physical data acquisition device provided by the utility model has the following beneficial effects:

the present invention provides a physical data acquisition device,

1. through the installation of being connected of heat-conducting component and heat-conducting plate, can accelerate the inside thermal derivation of device, then the starter motor, make the drive gear of installing on drive pivot outer wall rotate, then can drive the driven gear of meshing both sides about it also and follow the rotation, make the driven shaft of installing on two driven gear inner walls also can follow and rotate together, make not only can drive a plurality of first blades of installing on two first fixed cover outer walls and rotate, can also drive a plurality of second blades of installing on the fixed cover outer wall of second and also follow and rotate together, make the heat that produced air current was exported when a plurality of first blades rotated with a plurality of second blades discharge through the discharge port, thereby the radiating efficiency of device has been improved, the normal operating of device has also been ensured simultaneously.

2. And the cooling component is arranged in the inner wall of one side of the device, so that the cooling efficiency of the interior of the device can be further accelerated, and the safety of the device in operation is improved.

Drawings

FIG. 1 is a schematic structural diagram of a physical data acquisition device according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 housed in a first cavity and a second cavity;

FIG. 3 is a left side cross-sectional view of the device body of FIG. 1;

fig. 4 is an enlarged schematic view of a shown in fig. 1.

Reference numbers in the figures: 1. a device body; 2. a first cavity; 21. an outlet port; 22. a heat-dissipating web; 3. a heat conducting component; 31. a heat conducting plate; 32. a heat-conducting column; 33. a heat dissipation port; 5. a second cavity; 6. a cooling tank; 7. a motor; 8. a linkage assembly; 81. driving the rotating shaft; 82. a drive gear; 83. a driven gear; 84. a driven rotating shaft; 9. a cooling assembly; 91. a first fixing sleeve; 92. a first blade; 93. a second fixing sleeve; 94. a second blade; 10. a cooling assembly; 101. a U-shaped cooling tube; 102. and a flow guide pipe.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

Referring to fig. 1 to 3, a physical data acquisition device includes a device body 1, a first cavity 2 is formed inside the device body 1 near the rear side, a heat conduction assembly 3 is installed at a connection position between the first cavity 2 and the device body 1, a linkage assembly 8 is accommodated inside the first cavity 2, a motor 7 is installed at a driving end of the linkage assembly 8, a cooling assembly 9 is rotatably connected to the linkage assembly 8, discharge ports 21 are formed in outer walls of two sides of the device body 1, and the discharge ports 21 are communicated with the first cavity 2; the driving motor 7 drives the cooling component 9 to rotate in the first cavity 2 through the linkage component 8, and the generated air flow and the heat inside the carrying device body 1 are discharged through the discharge port 21.

When the heat dissipation device is used, when heat in the device body 1 needs to be dissipated and cooled, firstly, the heat in the device body 1 can be quickly guided into the first cavity 2 by installing the heat conduction plate 31 and the heat conduction column 32, then the driving gear 82 arranged on the outer wall of the driving rotating shaft 81 can rotate by starting the motor 7, then the driven gears 83 meshed on the upper and lower sides of the driving gear 83 can be driven to rotate, the driven rotating shafts 84 arranged on the inner walls of the two driven gears 83 can also rotate together, so that not only can a plurality of first blades 92 arranged on the outer walls of the two first fixing sleeves 91 be driven to rotate, but also a plurality of second blades 94 arranged on the outer walls of the second fixing sleeves 93 can be driven to rotate together, and the guided heat can be discharged through the discharge port 21 by air flow generated when the plurality of first blades 92 and the plurality of second blades 94 rotate, then, a large amount of heat in the device body 1 can be quickly dissipated and cooled, so that the heat dissipation efficiency of the device is improved, and the normal operation of the device is guaranteed.

As shown in fig. 1 and 4, the heat conducting component 3 includes a heat conducting plate 31 installed inside the device body 1 at the joint with the first cavity 2 through a connecting plate, a side surface of the heat conducting plate 31 far away from the first cavity 2 is fixed with the heat conducting plate 31 with a plurality of array equispaced, and a plurality of array equispaced heat dissipating ports 33 are opened on the surface of the heat conducting plate 31.

When the heat conduction device is used, the heat conduction plate 31 is provided with the heat conduction column 32, so that the efficiency of heat conduction in the first cavity 2 in the device body 1 can be improved, meanwhile, the heat conduction port 33 is formed, the heat in the device body 1 can be better conducted in the first cavity 2, and the efficiency of heat conduction in the first cavity 2 is further improved.

Referring to fig. 1 and 2, a heat dissipation net 22 is fixed inside the discharge port 21, and a plurality of filter holes are uniformly distributed in an array on the surface of the heat dissipation net 22.

When the dustproof heat dissipation device is used, the heat dissipation net 22 is arranged inside the discharge port 21, so that the heat dissipation efficiency is improved, external dust can be prevented from entering the first cavity 2, and the dustproof protection effect on parts inside the first cavity 2 is achieved.

Referring to fig. 2, the motor 7 is mounted to the rear surface of the apparatus body 1 through a shock-absorbing post.

When using, install motor 7 in the rear side of device body 1 through the shock absorber post, can cushion the vibrations that produce when motor 7 moves, also ensured the accurate nature of device when gathering data simultaneously.

Referring to fig. 2, the linkage assembly 8 includes a driving shaft 81 rotatably connected to the driving end of the motor 7, and one end of the driving shaft 81 far from the motor 7 extends into the first cavity 2 and is fixedly connected to a driving gear 82 at the end.

When the cooling device is used, the motor 7 is started, so that the driving rotating shaft 81 can rotate, and then the driving gear 82 can be driven to rotate, and preparation is made for driving the cooling assembly 9 to rotate later.

Referring to fig. 2, driven gears 83 are engaged with upper and lower sides of the driving gear 82, and driven shafts 84 are fixedly inserted into inner surfaces of the two driven gears 83.

When using, through drive gear 82's rotation, can drive the rotation of meshing at two driven gear 83 of its both sides for two driven rotating shaft 84 also can follow and rotate together, cause and can drive cooling module 9 and also follow and rotate together, make the air current that produces when cooling module 9 rotates can discharge leading-in heat to in the first cavity 2.

Referring to fig. 3, the cooling assembly 9 includes a first fixing sleeve 91 fixed to the end of the driving shaft 81 far from the driving gear 82, and a plurality of first blades 92 uniformly distributed in a circumferential array are fixed to the outer surface of the first fixing sleeve 91.

When the heat exchanger is used, the first blades 92 arranged on the outer surface of the first fixing sleeve 91 can be driven to rotate by the rotation of the driving rotating shaft 81, so that the heat conducted into the first cavity 2 can be cooled and discharged by the generated air flow when the first blades 92 rotate.

Referring to fig. 3, the cooling assembly 9 further includes a second fixing sleeve 93 fixed to the end of the driven rotating shaft 84 far from the driven gear 83, and a plurality of second blades 94 uniformly distributed in a circumferential array are fixed to an outer surface of the second fixing sleeve 93.

When the heat dissipation device is used, the rotation of the plurality of second blades 94 arranged on the two second fixing sleeves 93 can be driven simultaneously through the rotation of the two driven rotating shafts 84, so that the generated air flow can dissipate heat and cool heat in the first cavity 2 together with the air flow generated when the first blades 92 rotate, and the heat dissipation efficiency of the heat in the first cavity 2 can be further improved.

Referring to fig. 1 and 2, a second cavity 5 is formed in an inner wall of one side of the device body 1, a cooling module 10 for assisting in cooling heat inside the device body 1 is accommodated in the second cavity 5, a cooling tank 6 for storing cooling liquid is installed at an input end of the cooling module 10, and the cooling tank 6 is fixed to a rear side of the device body 1 and is located obliquely below the motor 7.

When using, through in the second cavity 5 that the inner wall was seted up at device body 1, installation cooling module 10 can assist the cooling again to the inside a large amount of heats that form of device body 1, has further improved the radiating efficiency of device body 1 again then.

Referring to fig. 2, the cooling assembly 10 includes a U-shaped cooling pipe 101 installed inside the second cavity 5 through a fixing block, a flow guide pipe 102 is connected to an end of the U-shaped cooling pipe 101, and one end of the flow guide pipe 102, which is far away from the U-shaped cooling pipe 101, extends to an outer wall of a rear side of the apparatus body 1 and is connected to the cooling box 6 to install a water pump.

When using, through the start-up water pump for coolant liquid in the cooling tank 6 leads to the inside to two U type cooling tubes 101 that are linked together through honeycomb duct 102, makes and to take away the surplus heat in the device body 1, then can further cool down, dispel the heat again to the heat in the device body 1 on the basis of first group cooling subassembly 9.

The working principle of the physical data acquisition device provided by the utility model is as follows: when heat in the device body 1 needs to be dissipated and cooled, firstly, the heat in the device body 1 can be quickly guided into the first cavity 2 by installing the heat conducting plate 31 and the heat conducting column 32, then the driving gear 82 installed on the outer wall of the driving rotating shaft 81 can rotate by starting the motor 7, then the driven gears 83 meshed on the upper and lower sides can be driven to rotate, the driven rotating shafts 84 installed on the inner walls of the two driven gears 83 can also rotate together, so that not only can a plurality of first blades 92 installed on the outer walls of the two first fixing sleeves 91 be driven to rotate, but also a plurality of second blades 94 installed on the outer walls of the second fixing sleeves 93 can be driven to rotate together, and the guided heat can be discharged through the discharge port 21 by air flow generated when the plurality of first blades 92 and the plurality of second blades 94 rotate, therefore, a large amount of heat in the device body 1 can be quickly radiated and cooled, so that the radiating efficiency of the device is improved, and the normal operation of the device is guaranteed; when still having a small amount of heats in the device body 1, can play the water pump earlier at this moment for coolant liquid in the cooler bin 6 leads to the inside to U type cooling tube 101 through honeycomb duct 102, through the cooling effect of coolant liquid, can take away the surplus heat in the device body 1, then can further cool down, dispel the heat again to the heat in the device body 1 on the basis of first group cooling subassembly 9.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The physical data acquisition device comprises a device body (1), and is characterized in that a first cavity (2) is formed in the inner part close to the rear side of the device body (1), a heat conduction assembly (3) is arranged at the joint of the first cavity (2) and the inner part of the device body (1), a linkage assembly (8) is accommodated in the first cavity (2), a motor (7) is installed at the driving end of the linkage assembly (8), a cooling assembly (9) is rotatably connected to the linkage assembly (8), discharge ports (21) are formed in the outer walls of the two sides of the device body (1), and the discharge ports (21) are communicated with the first cavity (2); the driving motor (7) drives the cooling component (9) to rotate in the first cavity (2) through the linkage component (8), and the generated air flow carries the heat inside the device body (1) and is discharged through the discharge port (21).

2. The physical data acquisition device according to claim 1, wherein the heat conducting component (3) comprises a heat conducting plate (31) which is arranged at the joint of the inside of the device body (1) and the first cavity (2) through a connecting plate, a plurality of heat conducting plates (31) with uniformly distributed arrays are fixed on the surface of one side of the heat conducting plate (31) far away from the first cavity (2), and a plurality of heat dissipating ports (33) with uniformly distributed arrays are formed in the surface of the heat conducting plate (31).

3. A physical data acquisition device according to claim 1, characterized in that the motor (7) is mounted to the rear surface of the device body (1) by means of shock-absorbing posts.

4. The physical data acquisition device according to claim 1, wherein the linkage assembly (8) comprises a driving rotating shaft (81) rotatably connected to the driving end of the motor (7), one end of the driving rotating shaft (81) far away from the motor (7) extends to the inside of the first cavity (2) and is fixedly sleeved with a driving gear (82) at the tail end.

5. The physical data acquisition device according to claim 4, wherein the upper side and the lower side of the driving gear (82) are respectively connected with a driven gear (83) in a meshing manner, and the inner surfaces of the two driven gears (83) are respectively and fixedly provided with a driven rotating shaft (84) in a penetrating manner.

6. A physical data acquisition device according to claim 5, wherein said cooling assembly (9) comprises a first fixing sleeve (91) fixed to the end of said driving shaft (81) remote from said driving gear (82), and a plurality of first blades (92) are fixed to the outer surface of said first fixing sleeve (91) and are uniformly distributed in a circumferential array.

7. The physical data acquisition device according to claim 5, wherein the cooling assembly (9) further comprises a second fixing sleeve (93) fixed to the end of the driven rotating shaft (84) far away from the driven gear (83), and a plurality of second blades (94) are uniformly distributed in a circumferential array and fixed to the outer surface of the second fixing sleeve (93).

8. The physical data acquisition device according to claim 1, characterized in that a second cavity (5) is formed in one side of the inner wall of the device body (1), a cooling assembly (10) for assisting in cooling the heat inside the device body (1) is accommodated in the second cavity (5), a cooling tank (6) for storing cooling liquid is installed at an input end of the cooling assembly (10), and the cooling tank (6) is fixed at the rear side of the device body (1) and is located obliquely below the motor (7).

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