CN117251342B - Big data-based network monitoring equipment - Google Patents

Abstract

The invention relates to a network monitoring device based on big data, which can realize that when a server generates larger heat due to excessive number of people accessing the server, the cooling liquid in a fan and a transmission hose can dissipate the heat of the server, and the temperature control valve is automatically closed after sensing the temperature rise by utilizing the temperature change of the cooling liquid in the transmission hose, the filter screen is subjected to ash removal by utilizing the flowing pressure of the cooling liquid, the air inlet quantity of the server is increased, the cooling liquid and the heat dissipation efficiency of the server are improved, in addition, when the server is in a high-temperature state for a long time, the mac position information of the device is sent to a cloud end by matching with a big data detection system, the provided mac position information can help the staff to quickly reach the vicinity of the server so as to facilitate the detection of the server, reduce the damage probability of the server due to high temperature, and further effectively reduce the data loss risk.

Description

Big data-based network monitoring equipment

Technical Field

The invention relates to network monitoring equipment, in particular to network monitoring equipment based on big data, which is applied to the technical field of network monitoring equipment.

Background

A server is a type of computer that runs faster, is more loaded, and is more expensive than a normal computer. The server provides computing or application services to other clients in the network (e.g., terminals such as PCs, smartphones, ATM, and even large devices such as train systems). The server has high-speed CPU operation capability, long-time reliable operation, strong I/O external data throughput capability and better expansibility, and generates a large amount of heat when the server processes larger data, so that heat dissipation and temperature monitoring equipment is generally installed in the server to ensure that the server can perform in a stable range when transmitting large data.

In order to solve the problem of data loss caused by poor heat dissipation of the server, the servers in the market are provided with heat dissipation devices and temperature monitoring equipment, and have a certain market ratio.

The existing heat dissipating device adopts a mode of water cooling and air cooling, namely, the water cooling is utilized to reduce the air inlet temperature and improve the heat dissipating effect, however, dust in the air can be blocked in a filter screen in the heat dissipating process, the heat dissipating effect is reduced, the data processing capacity of a server is reduced, even the server is damaged, and the data loss risk is improved.

Disclosure of Invention

Aiming at the prior art, the invention aims to solve the technical problems that dust in the air is blocked in a filter screen in the process of radiating, so that the radiating effect is reduced, the data processing capacity of a server is deteriorated, even the server is damaged, and the data loss risk is increased.

In order to solve the problems, the invention provides a network monitoring device based on big data, which comprises a server shell, a fan and a filter cartridge respectively arranged on the left side wall and the right side wall of the server shell, two cooling group pipes arranged inside the server shell, a water pump arranged on the lower side wall of the server shell and a plurality of transmission hoses communicated with the two cooling group pipes and the water pump;

the water pump is communicated with a water pipe, the inside sliding connection of the water pipe has an annular plug, the inside of the annular plug is provided with a temperature control valve, the upper end of the annular plug is fixedly connected with a piston, the upper end of the piston is fixedly connected with a driving rod, the water pipe is rotationally connected with a winding cylinder, the inner wall of the winding cylinder is provided with a threaded groove, the driving rod is positioned inside the threaded groove, the middle part of the winding cylinder is wound with a pull rope, the inside of the winding cylinder is fixedly connected with a filter screen, two crossed elastic plates are fixedly connected with one magnetic column at the crossing of the two elastic plates, the inside of the filter cylinder is fixedly connected with a fixed cylinder positioned on one side of the filter screen, the inside of the fixed cylinder is fixedly connected with a first magnetic column which is attracted with the magnetism of the magnetic column in a sliding manner, and the pull rope is fixedly connected with a thrust spring between the first magnetic column and the fixed cylinder.

In the network monitoring equipment based on big data, the internal temperature of the server can be monitored in real time through the cooling liquid, and the effects of improving heat dissipation and reminding are achieved when the temperature of the server is higher.

As a further improvement of the application, an L-shaped pipe is communicated between the water pipe and the conveying pipe, and the piston is positioned on one side of the L-shaped pipe.

As still further improvement of this application, fixedly connected with flexible bag between cooling group pipe and the cartridge filter, the inside sliding connection of server shell has the apron that is located cooling group pipe one side, equal fixedly connected with elastic rope between two inner walls about apron and the server shell, the winding reel upper and lower both ends all the wire-wound are connected with the wiring of apron fixed connection, and the wire-wound is reverse with the stay cord opposite.

As a further improvement of the application, grooves matched with the cooling group pipes are cut on the cover plate, and ventilation openings are cut at the grooves of the cover plate.

As a further improvement of the device, a plurality of evenly distributed pull balls are fixedly connected to the cover plate, and the pull balls penetrate through the cooling group pipe.

As a further improvement of the present application, the water pipe is fixedly connected with a reminding barrel on one side of the annular plug, the reminding barrel comprises a barrel shell, the barrel shell is internally and slidably connected with a movable plug, an exhaust hole is formed in the barrel shell, a tension spring is fixedly connected between the movable plug and the barrel shell, and an electric button is mounted on the right inner wall of the barrel shell.

As a supplement to the further improvement of the present application, the diameter of the upper and lower ends of the winding drum is larger than that of the middle part of the winding drum.

As still another improvement of this application, the electrical property button is connected with big data detecting system, and big data detecting system is including being used for obtaining the mac acquisition module of equipment mac address, be used for the network uploading module of data uploading and be used for the high in the clouds of record and monitoring, and mac acquisition module is connected with the network uploading module, and the network uploading module is connected with the high in the clouds.

In addition, the large data detection system is matched, when the server is in a high-temperature state for a long time, mac position information of the equipment is sent to the cloud, a timely reminding effect is achieved for the staff, the provided mac position information can help the staff to arrive at the vicinity of the server quickly, so that the server can be detected conveniently, the probability of damage of the server due to high temperature is reduced, and the risk of data loss is effectively reduced.

Drawings

FIG. 1 is a three-dimensional perspective view of a server housing according to a first embodiment of the present application;

fig. 2 is a schematic structural diagram of the inside of a server casing according to the first embodiment of the present application;

fig. 3 is a schematic structural view of a water pipe according to a first embodiment of the present application;

FIG. 4 is a dynamic diagram of the annular plug after closing in accordance with the first embodiment of the present application;

FIG. 5 is a schematic view showing the structure of the inside of the fixed cylinder according to the first embodiment of the present application;

fig. 6 is a schematic structural view of a cover plate part in the first embodiment of the present application;

fig. 7 is an external view of a cover plate in a second embodiment of the present application;

FIG. 8 is a schematic view of the structure of the cover plate contacting and separating from the cooling stack tube according to the second embodiment of the present application;

FIG. 9 is a state diagram of the cover plate contacting and separating from the cooling stack tube in the second embodiment of the present application;

FIG. 10 is a schematic view of the structure of the interior of the second embodiment of the present application;

fig. 11 is a system diagram in a second embodiment of the present application.

The reference numerals in the figures illustrate:

1 a server shell, 11 a fan, 12 a filter cartridge, 13 a cooling group pipe, 14 a transmission hose, 15 a water pump, 16 a transmission pipe, 17 an L-shaped pipe, 2 a water pipe, 21 an annular plug, 22 a temperature control valve, 23 a piston, 24 a driving rod, 3 a winding drum, 31 a pull rope, 4 a fixed drum, 41 a first magnetic column, 42 a thrust spring, 5 a filter screen, 51 an elastic plate, 52 a magnetic column, 6 a cover plate, 61 an elastic rope, 62 a winding rope, 63 a pull ball, 7 a telescopic bag, 8 a reminding drum, 81 a drum shell, 82 a movable plug and 83 an electric button.

Detailed Description

Two embodiments of the present application are described in detail below with reference to the accompanying drawings.

First embodiment:

fig. 1-2 show a big data based network monitoring device comprising a server housing 1, fans 11 and filter cartridges 12 respectively installed at both left and right side walls of the server housing 1, two cooling group pipes 13 installed inside the server housing 1, a water pump 15 installed at a lower side wall of the server housing 1, and a plurality of transmission hoses 14 communicating with the two cooling group pipes 13 and the water pump 15;

the water pump 15 is communicated with the water pipe 2, annular plug 21 is slidably connected inside the water pipe 2, temperature control valve 22 is mounted inside the annular plug 21, piston 23 is fixedly connected to the upper end of the annular plug 21, driving rod 24 is fixedly connected to the upper end of the piston 23, winding drum 3 is rotatably connected to the water pipe 2, a thread groove is cut in the inner wall of the winding drum 3, the driving rod 24 is located inside the thread groove, a pull rope 31 is wound on the middle of the winding drum 3, a filter screen 5 is fixedly connected to the inside of the filter drum 12, two elastic plates 51 which are arranged in a crossing mode are fixedly connected to the same magnetic column 52 on the filter screen 5, a fixed drum 4 which is located on one side of the filter screen 5 is fixedly connected to the inside of the filter drum 12, a first magnetic column 41 which is magnetically attracted with the magnetic column 52 is fixedly connected to the inside of the fixed drum 4, and a thrust spring 42 is fixedly connected between the first magnetic column 41 and the fixed drum 4.

When the number of the server access persons is excessive, a large amount of data processing can generate larger heat in the server, at the moment, the cooling liquid in the fan 11 and the transmission hose 14 can dissipate heat, the fan 11 can enable air to enter from the filter cylinder 12, and meanwhile, the cooling liquid in the cooling group pipe 13 can dissipate heat, the cooling liquid can circulate through the communication of the water pump 15, the transmission hose 14 and the cooling group pipe 13, when the server heat is excessively accumulated, the temperature of the cooling liquid in the transmission hose 14 can be increased, after the temperature control valve 22 senses the temperature increase, the temperature control valve is automatically closed, and then the annular plug 21 moves upwards under the flowing pressure of the cooling liquid, as shown in figure 4, at the moment, the piston 23 and the driving rod 24 move upwards together through the annular plug 21, the driving rod 24 can drive the winding drum 3 to rotate through the thread groove of the winding drum 3, the winding drum 3 is used for winding the pull rope 31, the pull rope 31 is used for pulling the first magnetic column 41 to move, the first magnetic column 41 is used for sucking the magnetic column 52 to move through magnetic force, the magnetic column 52 drives the elastic plate 51 to bend when moving, when the elastic plate 51 bends to a certain extent, the restoring force of the elastic plate 51 can overcome the magnetic force between the magnetic column 52 and the first magnetic column 41, the magnetic column 52 is driven to be rapidly separated from the first magnetic column 41 and smash the filter screen 5, the filter screen 5 is enabled to vibrate and shake off attached dust on the filter screen 5, accordingly, the permeability of the filter screen 5 is improved, the air intake of a server is increased, and the heat dissipation efficiency of cooling liquid and the server is improved.

Second embodiment:

figures 6-9 show that an L-shaped pipe 17 is communicated between the water outlet pipes 2 and 16, and a piston 23 is positioned on one side of the L-shaped pipe 17.

Fixedly connected with flexible bag 7 between cooling group pipe 13 and the cartridge filter 12, inside sliding connection of server shell 1 is located the apron 6 of cooling group pipe 13 one side, equal fixedly connected with elastic rope 61 between the upper and lower two inner walls of apron 6 and server shell 1, the equal round joint in both ends about the rolling tube 3 has the round rope 62 with apron 6 fixed connection, and the round rope 62's round joint is reverse with stay cord 31 in contrast, the cutting has the recess with cooling group pipe 13 assorted on the apron 6, the cutting has the vent in apron 6 recess department, fixedly connected with a plurality of evenly distributed draws ball 63 on the apron 6, and draw ball 63 runs through cooling group pipe 13 setting.

Fig. 10 shows that the water outlet pipe 2 is fixedly connected with a reminding barrel 8 positioned on one side of the annular plug 21, the reminding barrel 8 comprises a barrel shell 81, a movable plug 82 is slidably connected inside the barrel shell 81, an exhaust hole is cut on the barrel shell 81, a tension spring is fixedly connected between the movable plug 82 and the barrel shell 81, and an electric button 83 is arranged on the right inner wall of the barrel shell 81.

Meanwhile, when the winding drum 3 rotates, the winding rope 62 wound on the winding drum 3 is in an unreeling state, so that the cover plate 6 is in contact with the cooling group pipe 13 under the tension of the elastic rope 61, as shown in fig. 8, the cover plate 6 and the cooling group pipe 13 move towards the filter cartridge 12 together, the telescopic bag 7 is compressed after being subjected to pressure, and then air in the telescopic bag 7 is rapidly discharged from the filter screen 5, the reverse exhaust effect on the filter screen 5 is achieved, and the further cleaning effect on dust on the filter screen 5 is achieved.

The diameters of the upper end and the lower end of the winding drum 3 are larger than the middle part of the winding drum 3, when the winding drum 3 rotates, the winding drum 3 is different in length between the winding pull rope 31 and the unwinding winding rope 62 through the difference of the diameters of the upper end and the lower end and the middle part of the winding drum, so that the moving stroke of the cover plate 6 can be improved, and the exhaust ash removal effect is improved.

Fig. 11 shows that the electrical button 83 is connected with a big data detection system, and the big data detection system includes a mac acquisition module for acquiring a mac address of the device, a network uploading module for uploading data, and a cloud end for recording and monitoring, wherein the mac acquisition module is connected with the network uploading module, and the network uploading module is connected with the cloud end.

After the temperature of the cooling liquid drops, the temperature control valve 22 is automatically opened, at the moment, the cooling liquid can be discharged into the cooling liquid tank 16 through the annular plug 21 and the L-shaped pipe 17, meanwhile, the annular plug 21 moves downwards along with gravity and pulls the piston 23 to reset, the piston 23 drives the winding drum 3 to rotate and reset through the driving rod 24 after moving downwards, the pull rope 31 is unreeled and wound by the winding rope 62, when the server is in a high-temperature state for a long time, the temperature control valve 22 is closed for a long time, the annular plug 21 cannot descend to suck the movable plug 82, at the moment, the movable plug 82 moves slowly under the action of the tension spring until the movable plug 82 presses the electrical button 83, so that mac position information of equipment can be sent to the cloud end through the big data detection system, timely reminding is achieved for the staff, and the provided mac position information can help the staff to reach the vicinity of the server quickly, so that the server can be detected.

The scope of protection of the above-described embodiments employed in the present application is not limited to the above-described embodiments, and various changes made by those skilled in the art without departing from the spirit of the present application are still within the scope of protection of the present invention.

Claims (5)

1. A big data based network monitoring device comprising a server housing (1), characterized in that: the device comprises a server shell (1), a fan (11) and a filter cartridge (12) which are respectively arranged on the left side wall and the right side wall of the server shell (1), two cooling group pipes (13) arranged inside the server shell (1), a water pump (15) arranged on the lower side wall of the server shell (1) and a plurality of transmission hoses (14) communicated with the two cooling group pipes (13) and the water pump (15);

the utility model discloses a water pump, including water pump (15) and filter cartridge (12), water pipe (2) are connected with each other on, inside sliding connection of water pipe (2) has annular stopper (21), annular stopper (21) internally mounted has temperature control valve (22), annular stopper (21) upper end fixedly connected with piston (23), piston (23) upper end fixedly connected with actuating rod (24), rotate on water pipe (2) and be connected with rolling tube (3), rolling tube (3) inner wall has the screw groove, and actuating rod (24) are located the screw groove inside, rolling tube (3) middle part round connection has stay cord (31), filter cartridge (12) inside fixedly connected with filter screen (5), fixedly connected with two elastic plates (51) of alternately set up on filter screen (5), two elastic plates (51) crossing fixedly connected with same magnetic column (52), fixed cylinder (4) that are located one side of filter cartridge (12) fixedly connected with, fixed cylinder (4) inside sliding connection has first magnetic column (41) with magnetic column (52) and magnetic column (41) with first magnetic column (41) fixedly connected with first magnetic column (41), the cooling group pipe (13) and cartridge filter (12) between fixedly connected with flexible bag (7), inside sliding connection of server shell (1) has apron (6) that are located cooling group pipe (13) one side, equal fixedly connected with elastic rope (61) between two inner walls about apron (6) and server shell (1), winding rope (62) with apron (6) fixed connection are all articulated at both ends about winding cylinder (3), and winding rope (62) articulated reverse and stay cord (31) are opposite, the cutting has the recess with cooling group pipe (13) assorted on apron (6), apron (6) recess department cutting has the vent, fixedly connected with a plurality of evenly distributed draws ball (63) on apron (6), and draws ball (63) to run through cooling group pipe (13) and set up.

2. The big data based network monitoring device of claim 1, wherein: an L-shaped pipe (17) is communicated between the water pipe (2) and the conveying pipe (16), and the piston (23) is positioned on one side of the L-shaped pipe (17).

3. The big data based network monitoring device of claim 1, wherein: the utility model discloses a water pipe, including water pipe (2), water pipe (2) are gone up fixedly connected with and are located warning section of thick bamboo (8) of annular stopper (21) one side, warning section of thick bamboo (8) include barrel casing (81), the inside sliding connection of barrel casing (81) has removal stopper (82), the excavation has the exhaust hole on barrel casing (81), fixedly connected with tension spring between removal stopper (82) and barrel casing (81), electric button (83) are installed to barrel casing (81) right inner wall.

4. The big data based network monitoring device of claim 1, wherein: the diameters of the upper end and the lower end of the winding cylinder (3) are larger than the middle of the winding cylinder (3).

5. A big data based network monitoring device according to claim 3, characterized in that: the electrical button (83) is connected with a big data detection system, the big data detection system comprises a mac acquisition module for acquiring a mac address of equipment, a network uploading module for uploading data and a cloud end for recording and monitoring, the mac acquisition module is connected with the network uploading module, and the network uploading module is connected with the cloud end.