CN118159002A - Data acquisition device for big data processing - Google Patents

Abstract

The invention discloses a data acquisition device for big data processing, and particularly relates to the technical field of data acquisition devices. According to the data acquisition device for big data processing, the water circulation heat dissipation assembly and the cleaning assembly are arranged, so that the high temperature generated by the CPU and the GPU in the running process of the data acquisition device in the device shell is used for carrying out regional multi-source heat dissipation, unstable running or damage of the data acquisition device due to the high temperature can be effectively avoided, normal data acquisition is not affected, and the data acquisition device is convenient for workers to use.

Description

Data acquisition device for big data processing

Technical Field

The invention relates to the technical field of data acquisition devices, in particular to a data acquisition device for big data processing.

Background

Big data refers to a collection of data that is large in size and difficult to process in a reasonable amount of time with conventional software tools. The method has the characteristics of large capacity, multiple types, high processing speed and the like, and can bring high-value return. Big data are widely applied in the fields of medical health, public service, electronic commerce and the like, and assist accurate decision and resource allocation are optimized;

The data acquisition device is a device specially used for acquiring various physical quantities and signals, and can acquire various signal types including voltage, current, temperature, pressure, flow, speed, acceleration, displacement and the like. These devices typically convert the acquired data into digital signals and output to a computer or other device via an interface for further processing and analysis.

The Chinese patent document CN212659077U discloses a novel data acquisition device for big data processing, which belongs to the technical field of data acquisition devices for big data processing, and comprises a control table, wherein a cabinet body is welded at the lower end of the control table, a drawer is connected to the inner wall of the cabinet body in a matched sliding manner, a keyboard is arranged in the drawer, a display screen is arranged in the control table, a data panel is arranged at one side, far away from the display screen, of the control table, a radiator is arranged at the left side and the right side of the surface of the control table, two hinges are arranged at the upper end of the control table, a cover body is connected to the other side of the hinge in a matched manner, accessories and files to be carried are carried by the drawer, things to be carried by staff are saved greatly, a double-layer insurance method is adopted for protecting the outside in the aspect of security, the inside is protected by locking by a lock catch, the inside is protected by a built-in, the device is prevented from losing the internal files to be maximally protected, and the files are prevented from being leaked; however, the above patent documents still have the following drawbacks in the implementation process:

the above-mentioned patent can carry out double-deck insurance protection collection data to collection system in the implementation process, but can't carry out the subregion cooling to CPU and GPU in the data acquisition system in data acquisition system operation in-process, and then lead to data acquisition system because of the high temperature appears operating instability or damage easily, and then influences the collection of data, is inconvenient for the staff to use.

Disclosure of Invention

The invention mainly aims to provide a data acquisition device for big data processing, which can effectively solve the problem that the shell of the device cannot be cooled effectively in the running process.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows: the utility model provides a data acquisition device for big data processing, includes the device shell, device shell rear end middle part upside fixed mounting has the apron, device shell internal surface upper portion fixed mounting has control panel, the equal fixedly connected with supporting leg in device shell lower extreme four corners department, control panel lower extreme front portion fixed mounting has the data acquisition ware, control panel upper end rear portion left side fixed mounting has a plurality of wiring mouths, device shell internal surface front portion is provided with hydrologic cycle radiator unit, device shell left end front portion is provided with cleaning element.

Preferably, the hydrologic cycle radiating component includes two baffle one that all are connected with device shell internal surface fixed, device shell internal surface front portion is provided with pumping mechanism, the data acquisition ware lower extreme is provided with water-cooling mechanism, pumping mechanism inner chamber is provided with buoyancy mechanism, device shell internal surface lower part front side is provided with cooling mechanism, device shell left end front portion has been seted up the hole of placing that runs through device shell internal surface, place hole internal surface right part fixedly connected with filter screen, the filter screen internal surface is provided with blowing mechanism.

Preferably, the water pumping mechanism comprises a water tank fixedly connected with the front part of the inner surface of the device shell and a partition plate positioned at the front part, a partition plate II is fixedly connected with the middle part of the inner surface of the water tank, a limit groove is formed in the left end of the partition plate II, the right part of the inner surface of the water tank penetrates through and extends to a rear end fixedly connected with a water inlet pipe positioned at the rear partition plate, a water pump is fixedly arranged at the lower end of the water inlet pipe, the left side of the lower part of the inner surface of the water tank penetrates through and extends to a rear end fixedly connected with a water outlet pipe of the partition plate, a connecting pipe is fixedly connected with the front part of the inner surface of the water tank penetrates through and extends to the right part of the front end of the device shell, and a plugging plug is connected with the inner surface of the connecting pipe in a threaded manner.

Preferably, the water cooling mechanism comprises a rectangular plate fixedly connected with the lower end of the data acquisition device, a first round hole penetrating through the middle of the right end of the rectangular plate is formed in the middle of the left end of the rectangular plate, one ends of the water inlet pipe and the water outlet pipe, which are far away from the water tank, are fixedly connected with the right part and the left part of the inner surface of the round hole respectively, two trapezoid grooves are formed in linear distribution on the inner surface of the round hole, a first runner communicated with the inner surface of the trapezoid groove located on the right part is symmetrically formed in the front and back of the right part of the inner surface of the trapezoid groove, a second runner communicated with the inner surface of the round hole is symmetrically formed in the front and back of the left part of the trapezoid groove, a first baffle is fixedly connected with the lower part of the inner surface of the trapezoid groove and located on the left part, a plurality of second baffle baffles are fixedly connected with the upper end of the partition plate respectively, and a third left end middle part of the partition plate and the right end are fixedly connected with semicircular blocks on the upper part of the inner surface of the round hole respectively.

Preferably, the buoyancy mechanism comprises a buoyancy plate slidably connected with the inner surface of the limiting groove, a round hole II penetrating through the right end of the partition plate is formed in the lower portion of the left end of the partition plate II, a round ring barrel is fixedly connected to the inner surface of the round hole II, a round ring block is fixedly connected to the middle of the inner surface of the round ring barrel, springs are symmetrically and fixedly connected to the left end of the round ring block, two sealing blocks matched with the inner surface of the round ring barrel in size and shape are fixedly connected to the left end of the springs together, a connecting rope is fixedly connected to the middle of the left end of the sealing block, and one end, far away from the sealing block, of the connecting rope is fixedly connected with the middle of the lower end of the buoyancy plate.

Preferably, the cooling mechanism comprises three partition plates IV fixedly connected with the inner surface of the device shell and the lower end of the water tank, two rectangular grooves are linearly distributed at the left part of the front end of the water tank, semiconductor cooling fins are fixedly connected with the inner surface of the rectangular grooves, the cooling mechanism is positioned at the left part, a through hole III penetrating through and extending to the four right ends of the middle partition plate is formed in the front part of the four left ends of the partition plate, a vent pipe is fixedly connected with the inner surface of the round hole III, and an air inlet hole penetrating through the four right ends of the partition plate is formed in the rear part of the four left ends of the partition plate.

Preferably, the blowing mechanism comprises a water wheel blade which penetrates through the middle part of the left end of the filter screen and extends to the inner surface of the water tank to be connected in a rotating mode, a fan blade is fixedly connected to the middle part of the outer surface of the water wheel blade, a fixing block which is fixedly connected to the outer surface of the water wheel blade is arranged at the front part of the left part of the front end of the partition board, two exhaust holes which penetrate through the lower part of the inner surface of the outer shell of the device are formed in the left side of the front part of the lower part of the outer shell of the device, an arc-shaped block which is fixedly connected to the lower part of the left end of the water tank is arranged at the front part of the partition board, and a blocking block III is fixedly connected to the inner surface of the water tank above the water tank.

Preferably, the cleaning component comprises a circular ring groove formed in the middle of the inner surface of the placing hole, a cleaning mechanism is arranged on the right part of the inner surface of the circular ring groove, and a protection mechanism is arranged on the front part of the inner surface of the water vane.

Preferably, the cleaning mechanism comprises a toothed ring fixedly connected with the right part of the inner surface of the circular groove, a circular block is fixedly connected to the front part of the water wheel She Waibiao, a rotating rod is rotationally connected to the inner surface of the circular block, a gear which is in meshed connection with the toothed ring is fixedly connected to one end of the rotating rod, which is far away from the circular block, a circular rod is fixedly connected to the outer surface of the rotating rod, and a plurality of bristles are annularly distributed and fixedly connected to the outer surface of the circular rod.

Preferably, the protection mechanism comprises a connecting rod fixedly connected with the outer surface of the circular block, one end of the connecting rod, far away from the circular block, is fixedly connected with a protection ring, and the outer surface of the rotating rod is rotationally connected with the protection ring.

Compared with the prior art, the invention has the following beneficial effects:

According to the invention, the water circulation heat dissipation assembly and the cleaning assembly are arranged, so that the data collector in the device shell is subjected to high temperature generated by the CPU and the GPU in the operation process, and the heat dissipation of multiple sources in a partition manner is carried out, so that unstable operation or damage of the data collector due to the high temperature can be effectively avoided, normal data collection is not influenced, and the device is convenient for workers to use.

According to the invention, the water cooling mechanism is arranged, so that water entering the rectangular plate can enter the two trapezoid grooves respectively under the action of the first circular hole and the first runner, two heat sources can be radiated simultaneously, and the cooling liquid after absorbing heat can be discharged into the drain pipe in a concentrated manner under the cooperation of the third partition plate and the second runner, so that the cooling liquid inside the trapezoid grooves is at a low temperature, and the heat radiation is facilitated.

According to the invention, the cleaning mechanism and the blowing mechanism are arranged, so that the water vane can rotate, the fan blades can be simultaneously driven to rotate, and induced draft enters the device shell to radiate the semiconductor radiating fins, so that the semiconductor radiating fins are always in a low-temperature state, further, cooling liquid after absorbing heat can be continuously cooled, meanwhile, the rotation of the water vane drives the brush hair to rotate to clean the filter screen, the filter screen is prevented from being blocked, and the fan blades can not normally induced draft.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall partial cross-sectional structure of the present invention;

FIG. 3 is a schematic view of a water circulation heat sink assembly and cleaning assembly according to the present invention;

FIG. 4 is a schematic view of the placement hole and filter screen structure of the present invention;

FIG. 5 is a schematic view of the pump mechanism of the present invention;

FIG. 6 is a schematic diagram of a water cooling mechanism according to the present invention;

FIG. 7 is a schematic view of a separator plate three configuration of the present invention;

FIG. 8 is a schematic view of a buoyancy mechanism according to the present invention;

FIG. 9 is an exploded view of the cooling mechanism of the present invention;

FIG. 10 is a schematic cross-sectional view of a blower mechanism according to the present invention;

FIG. 11 is a schematic view of the explosion effect of the cleaning assembly of the present invention.

In the figure: 1. a device housing; 2. a cover plate; 3. a control panel; 4. support legs; 5. a wiring port; 6. a data collector; 7. a water circulation heat dissipation assembly; 71. a first partition board; 73. a water pumping mechanism; 731. a water tank; 732. a water pump; 733. a water inlet pipe; 734. a drain pipe; 735. a second partition board; 736. a connecting pipe; 737. sealing the plug; 74. a water cooling mechanism; 741. a round hole I; 742. a first runner; 743. a trapezoid groove; 744. a second flow passage; 745. a first blocking block; 746. a third partition board; 747. a second blocking block; 748. a semicircle block; 749. a rectangular plate; 75. a buoyancy mechanism; 751. a limit groove; 752. a round hole II; 753. a buoyancy plate; 754. a circular cylinder; 755. a circular ring block; 756. a spring; 757. a block; 758. a connecting rope; 76. a cooling mechanism; 761. rectangular grooves; 762. a semiconductor heat sink; 763. a fourth partition board; 764. a round hole III; 765. a vent pipe; 767. an air inlet hole; 77. a blowing mechanism; 771. an arc-shaped block; 772. a water vane; 773. a fixed block; 774. a fan blade; 775. an exhaust hole; 776. a third blocking block; 78. placing the hole; 79. a filter screen; 8. a cleaning assembly; 81. circular ring grooves; 82. a cleaning mechanism; 821. a circular block; 822. a rotating lever; 823. a toothed ring; 824. a gear; 825. a round bar; 826. brushing; 83. a protective mechanism; 831. a connecting rod; 832. and a guard ring.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

First, as shown in fig. 1 and fig. 2, a data acquisition device for big data processing includes a device housing 1, a cover plate 2 is fixedly installed on the upper side of the middle part of the rear end of the device housing 1, a control panel 3 is fixedly installed on the upper part of the inner surface of the device housing 1, supporting legs 4 are fixedly connected to four corners of the lower end of the device housing 1, a data acquisition device 6 is fixedly installed on the front part of the lower end of the control panel 3, a plurality of wiring ports 5 are fixedly installed on the left side of the rear part of the upper end of the control panel 3, a water circulation heat dissipation assembly 7 is arranged on the front part of the inner surface of the device housing 1, and a cleaning assembly 8 is arranged on the front part of the left end of the device housing 1.

In the implementation process of the embodiment, the data to be collected is connected with the wiring port 5 through the data line, the data collector 6 is controlled to operate through the switch on the control panel 3, so that the data collector 6 collects and analyzes the data, the data are displayed through the display on the control panel 3, and the data collector 6 dissipates heat through the cooperation of the water circulation heat dissipation component 7 and the cleaning component 8 in the operation process of the data collector 6.

The control panel 3 is a mature technical means in the existing control equipment, and the invention uses the controllable function and the structure and principle of the control panel are not explained.

The data collector 6 is a mature technical means in the existing data collecting equipment, and the invention uses the function of collecting and analyzing the data, and the structure and principle of the data collector are not explained.

Specifically, in order to realize the partition heat dissipation of the CPU and the GPU in the data collector 6, referring to fig. 3, 4, 5, 6, 7, 8, 9 and 10, in this embodiment, the water circulation heat dissipation assembly 7 includes two partition boards 71 which are fixedly connected with the inner surface of the device housing 1, the front portion of the inner surface of the device housing 1 is provided with a water pumping mechanism 73, the lower end of the data collector 6 is provided with a water cooling mechanism 74, the inner cavity of the water pumping mechanism 73 is provided with a buoyancy mechanism 75, the front side of the lower portion of the inner surface of the device housing 1 is provided with a cooling mechanism 76, the front portion of the left end of the device housing 1 is provided with a placement hole 78 penetrating through the inner surface of the device housing 1, the right portion of the inner surface of the placement hole 78 is fixedly connected with a filter screen 79, and the inner surface of the filter screen 79 is provided with a blowing mechanism 77.

Further, referring to fig. 3, 4, 5, 6, 7, 8, 9 and 10, in this embodiment, the pumping mechanism 73 includes a water tank 731 fixedly connected to the front portion of the inner surface of the device housing 1 and the partition plate 71 located at the front portion, a partition plate two 735 is fixedly connected to the middle portion of the inner surface of the water tank 731, a limit slot 751 is formed at the left end of the partition plate two 735, the right portion of the inner surface of the water tank 731 penetrates and extends to the rear end of the partition plate one 71 located at the rear portion and is fixedly connected to a water inlet pipe 733, the lower end of the water inlet pipe 733 is fixedly connected to a water pump 732, the left side of the lower portion of the inner surface of the water tank 731 penetrates and extends to the rear end of the partition plate one 71 and is fixedly connected to a water outlet pipe 734, the front portion of the inner surface of the water tank 731 penetrates and extends to the right portion of the front end of the device housing 1 and is fixedly connected to a connecting pipe 736, and the inner surface of the connecting pipe 736 is screwed to a sealing plug 737.

Further, referring to fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9 and fig. 10, in this embodiment, the water cooling mechanism 74 includes a rectangular plate 749 fixedly connected to the lower end of the data collector 6, a first round hole 741 penetrating through the middle of the right end of the rectangular plate 749 is formed in the middle of the left end of the rectangular plate 749, one ends of the water inlet pipe 733 and the water drain 734, which are far away from the water tank 731, are fixedly connected to the right portion and the left portion of the inner surface of the first round hole 741 respectively, two trapezoid grooves 743 are linearly distributed on the inner surface of the first round hole 741, a first runner 742 communicated with the inner surface of the right trapezoid groove 743 is symmetrically formed in front and back of the inner surface of the first round hole 741, a second runner 744 communicated with the inner surface of the first round hole 741 is symmetrically formed in front and back of the inner surface of the left portion of the first trapezoid groove 743, a plurality of blocking blocks 745 are fixedly connected to the lower portion of the inner surface of the right trapezoid groove 743, a third partition board is fixedly connected to the lower portion of the inner surface of the left trapezoid groove 743, the upper end 746 is fixedly connected to the third partition board is fixedly located below the inner surface of the first runner 742, the third is fixedly connected to the upper end of the third partition board 746, and the third partition board is fixedly connected to the upper end 746 is fixedly connected to the upper portion of the third partition board 746, and the upper end is fixedly connected to the upper half of the upper portion of the third partition board 747 is fixedly connected to the upper round square to the upper round hole to the upper surface of the upper half is.

In the implementation process, the sealing plug 737 is turned to be far away from the connecting pipe 736, the cooling liquid is placed into the water tank 731, at this time, the water pump 732 is started, the cooling liquid in the water tank 731 is pumped from the input end of the water pump 732, and enters the water inlet pipe 733, and enters the rectangular plate 749 through the round hole 741, at this time, the cooling liquid can enter the right trapezoid slot 743 under the pressurizing action of the water pump 732, and the flow rate is slowed down under the action of the blocking block 745, so that the cooling liquid absorbs heat to the first heat source, and at the same time, enters the left trapezoid slot 743 through the flow channel 742, and because the third partition 746 is fixedly connected with the left trapezoid slot 743, the cooling liquid which does not absorb heat enters the upper space formed by the third partition 746 and the left trapezoid slot 743, and slows down the flow rate under the action of the blocking block 747, so that the second heat source is cooled.

Secondly, the cooling liquid after the heat is absorbed by the two trapezoid grooves 743, the cooling liquid in the trapezoid groove 743 positioned at the right part enters the space below the partition plate three 746 and the trapezoid groove 743 positioned at the left part under the action of the partition plate three 746, and enters the drain pipe 734 through the first round hole 741, and meanwhile, the cooling liquid absorbing the heat in the space above the trapezoid groove 743 positioned at the left part flows into the first round hole 741 through the second flow passage 744, and then enters the drain pipe 734, so that the cooling of the CPU and the GPU in the data collector 6 is realized.

Further, referring to fig. 3,4, 5, 6, 7, 8, 9 and 10, in this embodiment, the buoyancy mechanism 75 includes a buoyancy plate 753 slidably connected with an inner surface of the limiting groove 751, a second round hole 752 penetrating through a right end of the second partition 735 is formed in a lower portion of a left end of the second partition 735, an annular cylinder 754 is fixedly connected to an inner surface of the second round hole 752, an annular block 755 is fixedly connected to a middle portion of an inner surface of the annular cylinder 754, springs 756 are symmetrically and fixedly connected to a front end and a rear end of the annular block 755, a blocking block 757 with a size and a shape matched with those of the inner surface of the annular cylinder 754 is fixedly connected to a left end of the blocking block 757, and one end of the connecting rope 758 away from the blocking block 757 is fixedly connected to a middle portion of a lower end of the buoyancy plate 753.

In the implementation process, the cooling liquid after absorbing heat enters the left space in the water tank 731 under the action of the drain pipe 734 and is accumulated in the left space of the water tank 731, so that the buoyancy plate 753 moves upwards under the buoyancy action of the cooling liquid, the buoyancy plate 753 pulls the connecting rope 758, the connecting rope 758 pulls the blocking block 757 to move, the pulling spring 756 is in a stretched state, the blocking block 757 is far away from the ring barrel 754, and at the moment, the cooling liquid enters the right space in the water tank 731 through the ring barrel 754.

Secondly, when the buoyancy provided by the left space cooling liquid in the water tank 731 is smaller than the tensile force of the spring 756, the blocking block 757 is reset under the tensile reaction of the spring 756, so that the annular cylinder 754 is in a closed state, the left cooling liquid cannot enter the right space in the water tank 731, and the cooling liquid in the left space of the water tank 731 has enough retention time to perform cooling treatment.

Further, referring to fig. 3, 4, 5, 6, 7, 8, 9 and 10, in this embodiment, the cooling mechanism 76 includes three partition plates four 763 fixedly connected to the inner surface of the device housing 1 and the lower end of the water tank 731, two rectangular grooves 761 are linearly distributed on the left part of the front end of the water tank 731, the inner surfaces of the two rectangular grooves 761 are fixedly connected with semiconductor cooling fins 762, a through hole three 764 penetrating and extending to the right end of the middle partition plate four 763 is formed on the front part of the left end of the left partition plate four 763, a ventilation pipe 765 is fixedly connected to the inner surface of the circular hole three 764, and an air inlet hole 767 penetrating the right end of the partition plate four 763 is formed on the rear part of the left end of the left partition plate four 763.

Further, referring to fig. 3, 4, 5,6 and 7, in this embodiment, the blowing mechanism 77 includes a water wheel blade 772 penetrating through the middle of the left end of the filter screen 79 and extending to the inner surface of the drain pipe 734 for rotation connection, the middle of the outer surface of the water wheel blade 772 is fixedly connected with a fan blade 774, the left part of the front end of the first front partition plate 71 is fixedly connected with a fixing block 773 rotationally connected with the outer surface of the water wheel blade 772, the left side of the front end of the lower end of the device housing 1 is provided with two exhaust holes 775 penetrating through the lower part of the inner surface of the device housing 1, the left part of the front end of the first front partition plate 71 is fixedly connected with an arc block 771 fixedly connected with the lower part of the left end of the water tank 731, and the inner surface of the drain pipe 734 is located above the water wheel blade 772 and fixedly connected with a blocking block three 776.

In the implementation process, after the cooling liquid flows into the left space in the water tank 731, the cooling liquid after absorbing heat is cooled by the semiconductor cooling fins 762, meanwhile, the flowing direction of the cooling liquid in the drain pipe 734 can be changed under the action of the blocking block three 776, so that the water vane 772 is driven to rotate, the fan blades 774 on the water vane 772 rotate, the cooling liquid is sucked into the device shell 1 through the filter screen 79 and moves downwards under the action of the arc block 771, the two semiconductor cooling fins 762 are blown and cooled respectively under the cooperation of the air inlet holes 767 and the vent pipes 765, and the semiconductor cooling fins 762 are in a low-temperature state and continuously cooled.

The semiconductor heat spreader 762 is a conventional heat dissipation technology in the prior art, and the principle of the semiconductor heat spreader is mainly based on the thermal characteristics and heat transfer phenomenon of the semiconductor material.

In the second embodiment, the cleaning assembly 8 for cleaning the sundries on the filter screen 79 when the air blowing mechanism 77 sucks air is added on the basis of the first embodiment, so that the purposes of cleaning the dust and sundries attached to the filter screen 79 and avoiding blockage are achieved.

Specifically, in order to clean dust and impurities attached to the filter screen 79 to avoid blockage, referring to fig. 3, 4 and 11, in this embodiment, the cleaning assembly 8 includes a circular ring groove 81 formed in the middle of the inner surface of the placement hole 78, a cleaning mechanism 82 is disposed on the right portion of the inner surface of the circular ring groove 81, and a protection mechanism 83 is disposed on the front portion of the inner surface of the water wheel blade 772.

Further, referring to fig. 3, 4 and 11, in this embodiment, the cleaning mechanism 82 includes a toothed ring 823 fixedly connected to the right portion of the inner surface of the annular groove 81, a circular block 821 is fixedly connected to the front portion of the outer surface of the water wheel blade 772, a rotating rod 822 is rotatably connected to the inner surface of the circular block 821, a gear 824 engaged with the toothed ring 823 is fixedly connected to one end of the rotating rod 822 away from the circular block 821, a circular rod 825 is fixedly connected to the outer surface of the rotating rod 822, and a plurality of bristles 826 are fixedly connected to the outer surface of the circular rod 825 in an annular distribution.

In the implementation process, some dust or sundries can be attached to the long-time back surface of the filter screen 79, along with the rotation of the water wheel 772, the water wheel 772 can drive the rotating rod 822 on the circular block 821 to rotate, and meanwhile, under the action of the meshing connection of the toothed ring 823 and the gear 824, the gear 824 rotates to drive the rotating rod 822 to rotate, so that the brush hair 826 on the rotating rod 822 can be driven to rotate, the brush hair 826 can repeatedly clean the dust and sundries attached to the filter screen 79, and further the filter screen 79 is prevented from being blocked, so that the semiconductor cooling fin 762 cannot effectively cool.

Further, referring to fig. 3,4 and 11, in the present embodiment, the protection mechanism 83 includes a connecting rod 831 fixedly connected to the outer surface of the circular block 821, one end of the connecting rod 831 away from the circular block 821 is fixedly connected with a protection ring 832, and the outer surface of the rotating rod 822 is rotatably connected to the protection ring 832.

In the implementation process, the circular block 821 can drive the connecting rod 831 to rotate in the rotating process, and because the connecting rod 831 and the protecting ring 832 are fixedly connected, the protecting ring 832 can rotate on the inner surface of the placing hole 78, so that the gear 824 and the toothed ring 823 are protected, sundries in the operation process are prevented from entering the circular groove 81, and the operation of the gear 824 and the toothed ring 823 is prevented from being influenced.

The working flow is as follows: when the device is used, the water pump 732 is started, so that cooling liquid enters the water cooling mechanism 74 through the water inlet pipe 733, the heat of multiple heat sources is dissipated to the data collector 6 through the water cooling mechanism 74, meanwhile, the cooling liquid can enter the left space inside the water tank 731 through the water drain pipe 734, the cooling liquid is retained in time under the action of the buoyancy mechanism 75, meanwhile, the semiconductor cooling fin 762 in the cooling mechanism 76 cools the cooling liquid after absorbing heat, the cooling liquid flows back into the right space inside the water tank 731 again through the buoyancy mechanism 75 to be cooled circularly, the water in the water drain pipe 734 can drive the water wheel blades 772 in the blowing mechanism 77 to rotate, the fan blades 774 absorb air into the inner cavity of the device shell 1 to dissipate the heat, and meanwhile, the water blades 772 rotate to drive the bristles 826 in the cleaning mechanism 82 to clean sundries attached to the filter screen 79.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a big data processing is with data acquisition device, includes device shell (1), its characterized in that: the device comprises a device housing (1), wherein a cover plate (2) is fixedly mounted on the upper side of the middle part of the rear end of the device housing (1), a control panel (3) is fixedly mounted on the upper part of the inner surface of the device housing (1), supporting legs (4) are fixedly connected to four corners of the lower end of the device housing (1), a data collector (6) is fixedly mounted on the front part of the lower end of the control panel (3), a plurality of wiring ports (5) are fixedly mounted on the left side of the rear part of the upper end of the control panel (3), a water circulation heat dissipation assembly (7) is arranged on the front part of the inner surface of the device housing (1), and a cleaning assembly (8) is arranged on the front part of the left end of the device housing (1).

2. The data acquisition device for big data processing according to claim 1, wherein: the utility model provides a hydrologic cycle radiating component (7) including two baffle one (71) that all are connected with device shell (1) internal surface fixed, device shell (1) internal surface front portion is provided with water pumping mechanism (73), data collection station (6) lower extreme is provided with water cooling mechanism (74), water pumping mechanism (73) inner chamber is provided with buoyancy mechanism (75), device shell (1) internal surface lower part front side is provided with cooling mechanism (76), device shell (1) left end front portion has been seted up and has been run through device shell (1) internal surface place hole (78), place hole (78) internal surface right part fixedly connected with filter screen (79), filter screen (79) internal surface is provided with blowing mechanism (77).

3. The data acquisition device for big data processing according to claim 2, wherein: the water pumping mechanism (73) comprises a water tank (731) fixedly connected with the front part of the inner surface of the device shell (1) and a first partition plate (71) positioned at the front part, a second partition plate (735) is fixedly connected to the middle part of the inner surface of the water tank (731), a limit groove (751) is formed in the left end of the second partition plate (735), the right part of the inner surface of the water tank (731) penetrates through and extends to the rear end of the first partition plate (71) positioned at the rear part, a water inlet pipe (733) is fixedly connected with a water pump (732), the left side of the lower part of the inner surface of the water tank (731) penetrates through and extends to the rear end of the first partition plate (71) and is fixedly connected with a water drain pipe (734), the front part of the inner surface of the water tank (731) penetrates through and extends to the right part of the front end of the device shell (1) and is fixedly connected with a connecting pipe (736), and the inner surface of the connecting pipe (736) is in threaded connection with a blocking plug (737).

4. A data acquisition device for big data processing according to claim 3, wherein: the water cooling mechanism (74) comprises a rectangular plate (749) fixedly connected with the lower end of the data collector (6), a first runner (742) penetrating through the middle of the right end of the rectangular plate (749) is arranged in the middle of the left end of the rectangular plate (749), one end of the water inlet pipe (733) and the water outlet pipe (734), which are far away from the water tank (731), is fixedly connected with the right part and the left part of the inner surface of the first runner (741) respectively, two trapezoid grooves (743) are linearly distributed on the inner surface of the first runner (741), a first runner (742) communicated with the inner surface of the right trapezoid groove (743) is symmetrically arranged in the front and the back of the left part of the inner surface of the trapezoid groove (743), a second runner (744) communicated with the inner surface of the first runner (741) is arranged in the right part of the trapezoid groove (743), a plurality of blocking blocks (745) are fixedly connected to the lower part of the inner surface of the trapezoid groove (743) respectively, two trapezoid grooves (743) are linearly distributed on the inner surface of the first runner (741), three trapezoid grooves (742) are symmetrically arranged on the front and back of the inner surface of the right part of the trapezoid groove (743) respectively, three blocking blocks (746) are fixedly connected with the upper end of the first runner (747) and the upper end of the third partition plate (747) respectively.

5. A data acquisition device for big data processing according to claim 3, wherein: buoyancy mechanism (75) include with spacing groove (751) internal surface sliding connection's buoyancy board (753), round hole two (752) that run through baffle two (735) right-hand member are seted up to baffle two (735) left end lower part, round hole two (752) internal surface fixedly connected with ring section of thick bamboo (754), ring section of thick bamboo (754) internal surface middle part fixedly connected with ring piece (755), symmetry fixedly connected with spring (756) around ring piece (755) left end, two common fixedly connected with of spring (756) left end is with shutoff piece (757) of ring section of thick bamboo (754) internal surface looks size and shape looks adaptation, shutoff piece (757) left end middle part fixedly connected with connecting rope (758), one end that shutoff piece (757) were kept away from to connecting rope (758) and buoyancy board (753) lower extreme middle part fixedly connected.

6. A data acquisition device for big data processing according to claim 3, wherein: the cooling mechanism (76) comprises three partition boards IV (763) fixedly connected with the inner surface of the device shell (1) and the lower end of the water tank (731), two rectangular grooves (761) are linearly distributed at the left part of the front end of the water tank (731), semiconductor cooling fins (762) are fixedly connected to the inner surfaces of the two rectangular grooves (761), a through hole III (764) penetrating and extending to the right end of the middle partition board IV (763) is formed in the front part of the left end of the partition board IV (763), a vent pipe (765) is fixedly connected to the inner surface of the hole III (764), and an air inlet hole (767) penetrating through the right end of the partition board IV (763) is formed in the rear part of the left end of the partition board IV (763).

7. A data acquisition device for big data processing according to claim 3, wherein: the blowing mechanism (77) comprises a water wheel blade (772) penetrating through the middle of the left end of the filter screen (79) and extending to the inner surface of the drain pipe (734) to be rotationally connected, a fan blade (774) is fixedly connected to the middle of the outer surface of the water wheel blade (772), a fixing block (773) which is fixedly connected to the outer surface of the water wheel blade (772) is fixedly connected to the left of the front end of the first partition board (71), two exhaust holes (775) penetrating through the lower portion of the inner surface of the device housing (1) are formed in the left of the front portion of the lower end of the device housing (1), an arc block (771) fixedly connected to the lower portion of the left of the water tank (731) is fixedly connected to the left of the front end of the first partition board (71), and a blocking block (776) is fixedly connected to the inner surface of the drain pipe (734) above the water wheel blade (772).

8. The data acquisition device for big data processing according to claim 7, wherein: the cleaning assembly (8) comprises a circular ring groove (81) formed in the middle of the inner surface of the placement hole (78), a cleaning mechanism (82) is arranged on the right portion of the inner surface of the circular ring groove (81), and a protection mechanism (83) is arranged on the front portion of the inner surface of the water wheel blade (772).

9. The data acquisition device for big data processing according to claim 8, wherein: the cleaning mechanism (82) comprises a toothed ring (823) fixedly connected with the right part of the inner surface of the circular ring groove (81), a circular block (821) is fixedly connected to the front part of the outer surface of the water wheel blade (772), a rotating rod (822) is rotatably connected to the inner surface of the circular block (821), a gear (824) meshed with the toothed ring (823) is fixedly connected to one end of the rotating rod (822) away from the circular block (821), a circular rod (825) is fixedly connected to the outer surface of the rotating rod (822), and a plurality of bristles (826) are annularly distributed and fixedly connected to the outer surface of the circular rod (825).

10. The data acquisition device for big data processing according to claim 9, wherein: the protection mechanism (83) comprises a connecting rod (831) fixedly connected with the outer surface of the circular block (821), one end, far away from the circular block (821), of the connecting rod (831) is fixedly connected with a protection ring (832), and the outer surface of the rotating rod (822) is rotationally connected with the protection ring (832).