CN117850551A - Big data-based information processing system - Google Patents

Abstract

The invention relates to the technical field of information processing, and discloses an information processing system based on big data, which comprises a shell mechanism, wherein the shell mechanism also comprises an equipment shell, when the invention is used, an extrusion long plate and a pushing column are affected by the expansion of an electric telescopic rod to generate movement, in the moving process, air in an air box is forced to be transmitted into an air transmission square pipe, the air is injected into an extrusion air bag through the air transmission pipe and an air inlet pipe, the sliding gap between a sliding groove and a baffle is filled through the expanded extrusion air bag, the air tightness of the equipment is improved, the expansion and contraction generated by the electric telescopic rod are utilized, the distance between a heating plate and a supporting bracket is changed by the change of the electric telescopic rod, when the distance between the supporting bracket and the heating plate is increased, the extrusion rod and a cleaning cross rod are affected by the tensile force to approach to the center position, so that the cleaning of the outer wall of the heating plate is completed, and the dust on the outer wall of the heating plate is prevented from being covered by the heating plate, and the heat conductivity of the heating plate is influenced.

Description

Big data-based information processing system

Technical Field

The invention relates to the technical field of information processing equipment, in particular to an information processing system based on big data.

Background

An information processing system of big data is a computing system for processing a large-scale dataset, aiming at efficiently storing, managing, analyzing and extracting value information. These systems incorporate various technologies and tools to address challenges presented by large data volumes, high speeds and diversity to enable processing and analysis of the mass data, but the large data itself requires a large number of servers, sensors and storage for collection and management, where the protective power box needs to be adjusted differently for different environments.

The gobi environment is wide and thin, and because of the large temperature difference between the high temperature in the daytime and the low temperature at night, the electronic components of most electronic equipment are damaged after the temperature difference is repeatedly experienced, and the workers are required to drive the vehicle to repair, which is time-consuming and labor-consuming, and the following scheme is provided for the problems.

Disclosure of Invention

In order to solve the technical problems, the invention provides an information processing system based on big data, which comprises a shell mechanism, wherein the shell mechanism also comprises an equipment shell, a collecting inclined plate is fixedly connected to the outer wall of the equipment shell, and a condensation plate is fixedly connected to the inner wall of the collecting inclined plate;

the sealing mechanism comprises a first air box fixedly connected to the side wall of the equipment shell, an extrusion long plate is connected to the inner wall of the first air box in a sliding mode, and a pushing column is fixedly connected to the side wall of the extrusion long plate;

the control mechanism comprises a supporting bracket fixedly connected to the outer wall of the collecting inclined plate, one end of the supporting bracket, far away from the collecting inclined plate, is rotationally connected with an extrusion rod, and one end, far away from the supporting bracket, of the extrusion rod is rotationally connected with a cleaning cross rod.

Preferably, the shell mechanism further comprises a sliding groove formed in the side wall of the equipment shell, the inner wall of the sliding groove is connected with a baffle in a sliding mode, and the inner wall of the sliding groove is fixedly connected with an extrusion air bag.

Preferably, the shell mechanism further comprises a telescopic square tube which is slidably connected to the inner wall of the collecting inclined plate, a limiting plate is slidably connected to the inner wall of the telescopic square tube, an extruding plate is slidably connected to the inner wall of the limiting plate, an electric telescopic rod is fixedly connected to the side wall of the equipment shell, one end of the electric telescopic rod, which is far away from the equipment shell, is fixedly connected with a pressing support, one end of the pressing support, which is far away from the electric telescopic rod, is fixedly connected with the side wall of the extruding plate, when the external environment temperature is too low, the extruding plate moves to the outermost periphery due to cold shrinkage, is connected with the inner wall of the limiting plate, external air enters the equipment shell through a gap between the extruding plate and the limiting plate, after the internal air pressure and the external air pressure of the equipment are in a stable state, the extruding plate is extruded by the electric telescopic rod and moves to the inside of the equipment, so that the closed space of the equipment shell, the telescopic square tube and the inner wall of the extruding plate is gradually converted from normal air pressure to high pressure, and the internal temperature of the equipment is improved.

Preferably, the sealing mechanism further comprises a fixed plate fixedly connected to the side wall of the pushing column, the bottom of the fixed plate is fixedly connected with the outer wall of the pressing support, the top of the first air box is in through connection with the first check valve, the top of the first air box is in through connection with the gas transmission square pipe, when temperature rising and temperature lowering are completed, due to the fact that a large temperature difference exists between the internal temperature and the external temperature of the equipment, when the external environment temperature is low and the internal temperature of the equipment is high, the equipment shell can condense water drops at the inner wall, the water drops move downwards along the inner wall of the condensation plate and contact with the inner wall of the extrusion plate, moisture is finally condensed and drops on the inner wall of the equipment shell, evaporation is achieved when the subsequent high temperature is waited, and through the application of the components, the fact that the inner wall is moist and the service life of equipment in the box are influenced can be effectively avoided.

Preferably, the sealing mechanism further comprises a second check valve which is connected with the inner wall of the gas transmission square tube in a penetrating manner, a gas transmission pipe is connected with the outer wall of the second check valve in a penetrating manner, one end of the gas transmission pipe, which is far away from the second check valve, is connected with a gas inlet pipe in a penetrating manner, the bottom of the gas inlet pipe is connected with the top of the extrusion air bag in a penetrating manner, when moisture is collected in the mode, as the extrusion plate is contacted with the moisture in the procedure, when a small gap is formed between the extrusion plate and the limiting plate in the follow-up working process, air can carry part of dust into the device, but because the inner wall of the extrusion plate is more moist, part of dust can be absorbed, the quantity of the dust entering the device is reduced, and in addition, as the distance between the limiting plate and the telescopic square tube is influenced by the electric telescopic rod, and when the distance between the limiting plate and the telescopic square tube is increased, the cleaning rod can clean the inner wall of the extrusion plate once.

Preferably, the sealing mechanism further comprises a first sliding rail fixedly connected with the inner wall of the limiting plate, a cross is slidably connected to the inner wall of the first sliding rail, a second sliding rail is slidably connected to one end, far away from the first sliding rail, of the cross, a cleaning rod is fixedly connected to the side wall of the cross, and the outer wall of the cleaning rod is slidably connected with the outer wall of the extruding plate.

Preferably, the control mechanism further comprises a second air box fixedly connected to the side wall of the limiting plate, one end of the second air box, which is far away from the limiting plate, is fixedly connected with a heating plate, an air pressure tank is connected to the side wall of the second air box in a penetrating manner, when the control mechanism is used, the long extrusion plate and the pushing column are affected by the expansion of the electric telescopic rod, movement is generated, in the moving process, air in the first air box is forced to be transmitted to the inside of the air transmission square tube, air is injected into the extrusion air bag through the air transmission tube and the air inlet tube, the sliding gap between the sliding groove and the baffle is filled through the expanded extrusion air bag, the air tightness of the equipment is improved, the expansion generated by the electric telescopic rod is utilized, the distance between the heating plate and the supporting bracket is changed by the electric telescopic rod, when the distance between the supporting bracket and the heating plate is improved, the extrusion rod and the cleaning cross rod are affected by the tension to approach the center, cleaning of the outer wall of the heating plate is completed, and the dust on the outer wall of the heating plate is prevented from being covered, and the heat conductivity of the heating plate is affected.

The invention has the following beneficial effects:

(1) The invention utilizes the characteristics that high temperature can be generated by high pressure formed by heat expansion and cold contraction and compressed air, and the temperature is reduced by negative pressure, when the external environment temperature is too high, the heating plate absorbs a large amount of heat and forces the air in the air box II to expand, the expansion gas drives the control rod and the limiting rod to move by pushing the pushing plate, the state shown in figure 8 is shown, the electric telescopic rod improves the pushing force, the electric telescopic rod drives the extruding plate to move outwards by pressing the support, but the limiting rod limits, the extruding plate and the telescopic square tube form a closed space, and the continuous external movement of the electric telescopic rod forces the closed space of the equipment shell, the telescopic square tube and the inner wall of the extruding plate to form the negative pressure, so that the internal temperature of the equipment shell is reduced, on the other hand, when the external environment temperature is too low, the limiting rod does not limit the extruding plate any more, the extruding plate moves to the outermost periphery, the external air is connected with the inner wall of the limiting plate, and the external air enters the inside the equipment shell through a gap between the extruding plate and the inner wall of the limiting plate, after the internal air pressure and the equipment is in a stable state, the extruding plate is extruded by the electric telescopic rod, the extruding plate moves towards the inside the equipment, so that the equipment shell, the equipment inner wall and the air pressure and the inner wall of the equipment can gradually change from the closed space to the inner wall of the equipment shell and the inner wall of the equipment, and the air pressure can be gradually changed from the high temperature to the normal environment temperature, and the normal temperature, and the temperature can be suitable for the equipment.

(2) When the device is used, the extrusion long plate and the pushing column are affected by the expansion and contraction of the electric telescopic rod to generate movement, in the moving process, air in the air box is forced to be transmitted into the air transmission square tube, the air is injected into the extrusion air bag through the air transmission tube and the air inlet tube, the sliding gap between the sliding groove and the baffle is filled by the expanded extrusion air bag, the air tightness of the device is improved, in addition, the expansion and contraction generated by the electric telescopic rod is utilized, the distance between the heating plate and the supporting bracket is changed by the change of the electric telescopic rod, when the distance between the supporting bracket and the heating plate is improved, the extrusion rod and the cleaning cross rod are affected by the tensile force to approach the center position, the cleaning of the outer wall of the heating plate is completed, and the influence on the heat conductivity of the heating plate due to the covering of dust on the outer wall of the heating plate is avoided.

(3) When the temperature rise and the temperature reduction are completed, as a large temperature difference exists between the internal temperature and the external temperature of the equipment, when the external environment temperature is low and the internal temperature of the equipment is high, the equipment shell can condense water drops at the inner wall, the water drops move downwards along the inner wall of the condensation plate and contact with the inner wall of the extrusion plate, and finally, the moisture is condensed and drops on the inner wall of the equipment shell to be evaporated when waiting for the subsequent high temperature, and through the application of the components, the problem that the inner wall is moist and the service life of equipment in a box is influenced due to the fact that the temperature difference between the inner wall and the outer wall is too large can be effectively avoided.

(4) When the water is collected in the mode, the extruding plate is contacted with the water in the working procedure, and when a small gap is formed between the extruding plate and the limiting plate in the follow-up working, part of dust is carried by air into the device, but part of dust can be absorbed by the inner wall of the extruding plate, so that the quantity of the dust entering the device is reduced, in addition, the distance between the limiting plate and the telescopic square tube is influenced by the electric telescopic rod, and when the distance between the limiting plate and the electric telescopic rod is increased, the inner wall of the extruding plate is cleaned once by the cleaning rod.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

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

FIG. 3 is a schematic cross-sectional view of the internal components of the housing mechanism of the present invention;

FIG. 4 is a schematic cross-sectional view of the housing mechanism of the present invention;

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

FIG. 6 is a schematic view of the internal components of the sealing mechanism of the present invention;

FIG. 7 is a schematic cross-sectional view of a control mechanism of the present invention;

fig. 8 is an enlarged view of a of fig. 7 in accordance with the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

in the figure: 1. a housing mechanism; 101. an equipment housing; 102. collecting inclined plates; 103. a condensation plate; 104. a sliding groove; 105. a baffle; 106. extruding the air bag; 107. a telescopic square tube; 108. a limiting plate; 109. an extrusion plate; 110. an electric telescopic rod; 111. pressing the support; 2. a sealing mechanism; 201. an air box I; 202. extruding the long plate; 203. pushing the column; 204. a fixing plate; 205. a first check valve; 206. a gas transmission square tube; 207. a second check valve; 208. a gas pipe; 209. an air inlet pipe; 210. a first sliding rail; 211. a cross; 212. sliding rails II; 213. a cleaning lever; 3. a control mechanism; 301. a support bracket; 302. an extrusion rod; 303. cleaning the cross bar; 304. a second gas tank; 305. a heating plate; 306. an air pressure tank; 307. a pushing plate; 308. a control lever; 309. and a restraining bar.

Detailed Description

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

Referring to fig. 1-3, the present invention is an information processing system based on big data, which includes a housing mechanism 1, the housing mechanism 1 further includes a device housing 101, a collecting inclined plate 102 is fixedly connected to an outer wall of the device housing 101, and a condensation plate 103 is fixedly connected to an inner wall of the collecting inclined plate 102;

the sealing mechanism 2 comprises a first air box 201 fixedly connected to the side wall of the equipment shell 101, an extrusion long plate 202 is slidably connected to the inner wall of the first air box 201, and a pushing column 203 is fixedly connected to the side wall of the extrusion long plate 202;

the control mechanism 3, the control mechanism 3 includes the support bracket 301 of fixed connection in collection swash plate 102 outer wall department, and the one end that the support bracket 301 kept away from collection swash plate 102 rotates and is connected with the squeeze lever 302, and the one end that the squeeze lever 302 kept away from the support bracket 301 rotates and is connected with clean horizontal pole 303.

The shell mechanism 1 further comprises a sliding groove 104 formed in the side wall of the equipment shell 101, a baffle 105 is slidably connected to the inner wall of the sliding groove 104, and an extrusion air bag 106 is fixedly connected to the inner wall of the sliding groove 104.

The shell mechanism 1 further comprises a telescopic square tube 107 which is slidably connected to the inner wall of the collecting inclined plate 102, a limiting plate 108 is slidably connected to the inner wall of the telescopic square tube 107, an extruding plate 109 is slidably connected to the inner wall of the limiting plate 108, an electric telescopic rod 110 is fixedly connected to the side wall of the equipment shell 101, a pressing support 111 is fixedly connected to one end of the electric telescopic rod 110, which is far away from the equipment shell 101, and one end of the pressing support 111, which is far away from the electric telescopic rod 110, is fixedly connected with the side wall of the extruding plate 109.

Referring to fig. 4-8, the present invention is an information processing system based on big data, on the basis of the first embodiment, the sealing mechanism 2 further includes a fixing plate 204 fixedly connected to the side wall of the pushing post 203, the bottom of the fixing plate 204 is fixedly connected to the outer wall of the pressing bracket 111, the top of the first air box 201 is connected to the first check valve 205 in a penetrating manner, and the top of the first air box 201 is connected to the air pipe 206 in a penetrating manner, when the temperature rise and the temperature fall are completed, because of a large temperature difference between the internal temperature and the external temperature of the device, when the external environment temperature is low and the internal temperature of the device is high, the device housing 101 condenses water droplets on the inner wall of the condensation plate 103, and the water droplets move downwards along the inner wall of the extrusion plate 109 and finally condense and drop on the inner wall of the device housing 101, and evaporate when waiting for the subsequent high temperature.

The sealing mechanism 2 further comprises a second one-way valve 207 which is connected to the inner wall of the air delivery square tube 206 in a penetrating manner, an air delivery pipe 208 is connected to the outer wall of the second one-way valve 207 in a penetrating manner, an air inlet pipe 209 is connected to one end of the air delivery pipe 208 away from the second one-way valve 207 in a penetrating manner, the bottom of the air inlet pipe 209 is connected to the top of the extrusion air bag 106 in a penetrating manner, when moisture is collected in the above-mentioned manner, as the extrusion plate 109 contacts with the moisture in the above-mentioned process, when a small gap is formed between the extrusion plate 109 and the limiting plate 108 in the subsequent operation, air will carry part of dust into the device, but because the inner wall of the extrusion plate 109 is wet, part of dust can be absorbed, the amount of dust entering the device is reduced, in addition, as the distance between the limiting plate 108 and the telescopic square tube 107 is influenced by the electric telescopic rod 110, and when the distance between the two is increased, the cleaning rod 213 will clean the inner wall of the extrusion plate 109 once.

The sealing mechanism 2 further comprises a first sliding rail 210 fixedly connected with the inner wall of the limiting plate 108, a cross 211 is slidably connected with the inner wall of the first sliding rail 210, a second sliding rail 212 is slidably connected with one end, far away from the first sliding rail 210, of the cross 211, a cleaning rod 213 is fixedly connected with the side wall of the cross 211, and the outer wall of the cleaning rod 213 is slidably connected with the outer wall of the extruding plate 109.

The control mechanism 3 further comprises a second air box 304 fixedly connected to the side wall of the limiting plate 108, a heating plate 305 is fixedly connected to one end, away from the limiting plate 108, of the second air box 304, an air pressure tank 306 is connected to the side wall of the second air box 304 in a penetrating manner, when the control mechanism is used, the extrusion long plate 202 and the pushing column 203 are affected by the expansion and contraction of the electric telescopic rod 110 to move, in the moving process, air in the first air box 201 is forced to be transmitted into the air conveying square tube 206, the air is injected into the extrusion air bag 106 through the air pipe 208 and the air inlet tube 209, sliding gaps between the sliding groove 104 and the baffle 105 are filled through the expanded extrusion air bag 106, the air tightness of equipment is improved, in addition, the distance between the heating plate 305 and the supporting bracket 301 is changed by the electric telescopic rod 110, when the distance between the supporting bracket 301 and the heating plate 305 is increased, the extrusion rod 302 and the cleaning cross rod 303 are affected by the central position of the cleaning cross rod 303 to approach the center of the heating plate 305, and cleaning of the outer wall of the heating plate 305 is completed, and dust of the heating plate 305 is prevented from being covered by the outer wall of the heating plate 305, and the tensile force is affected.

The control mechanism 3 further comprises a pushing plate 307 which is slidably connected to the inner wall of the air pressure tank 306, a control rod 308 is fixedly connected to the side wall of the pushing plate 307, a limiting rod 309 is fixedly connected to one end of the control rod 308 away from the pushing plate 307, high pressure is formed by utilizing the characteristics of thermal expansion and contraction and compressed air to generate high temperature and negative pressure to reduce temperature, when the external environment temperature is too high, the heating plate 305 absorbs a large amount of heat and forces air in the air box II 304 to expand, the expanding air drives the control rod 308 and the limiting rod 309 to move through pushing the pushing plate 307, the electric telescopic rod 110 is pushed to push the pushing force, the electric telescopic rod 110 drives the extruding plate 109 to move outwards through the pressing support 111, but the limiting rod 309 is limited, the extruding plate 109 and the telescopic square tube 107 form a closed space, and due to the continuous outward movement of the electric telescopic rod 110, the closed space of the inner wall of the equipment shell 101, the telescopic square tube 107 and the extruding plate 109 is forced to form negative pressure, and therefore the internal temperature of the equipment shell 101 is reduced.

One specific application of this embodiment is: the invention utilizes the characteristics that high temperature is generated by high pressure formed by expansion and contraction with compressed air and the temperature is reduced by negative pressure, when the external environment temperature is too high, the heating plate 305 absorbs a large amount of heat and forces the air in the air box II 304 to expand, the expanding gas drives the control rod 308 and the limiting rod 309 to move by pushing the pushing plate 307, the state shown in figure 8 is shown, and at the moment, the electric telescopic rod 110 increases the thrust, the electric telescopic rod 110 drives the extruding plate 109 to move outwards by pressing the bracket 111, but the limiting rod 309 limits the extruding plate 109 and the telescopic square tube 107 to form a closed space, and because the continuous external movement of the electric telescopic rod 110 forces the closed space of the equipment shell 101, the telescopic square tube 107 and the inner wall of the extruding plate 109 to form negative pressure, thereby reducing the internal temperature of the equipment shell 101, on the other hand, when the external environment temperature is too low, the extrusion plate 109 moves to the outermost periphery outwards due to cold shrinkage and is connected with the inner wall of the limiting plate 108, external air enters the equipment shell 101 through a gap between the extrusion plate 109 and the limiting plate 108, after the internal and external air pressures of the equipment are in a stable state, the extrusion plate 109 is extruded by the electric telescopic rod 110 and moves towards the inside of the equipment, so that the airtight space of the equipment shell 101, the telescopic square tube 107 and the inner wall of the extrusion plate 109 is gradually converted from normal air pressure to high pressure, the internal temperature of the equipment is improved, the equipment does not need to manually change modes through the application of the components, the electric power box can be suitable for the environment with a large temperature difference in Gobi environment, when the electric power box is used, the extrusion long plate 202 and the pushing column 203 are influenced by the expansion and contraction of the electric telescopic rod 110 to generate movement, in the movement process, the air in the first air box 201 is forced to be transmitted into the air conveying square tube 206, and through gas-supply pipe 208 and income trachea 209 with the air injection extrusion gasbag 106 inside, fill the slip gap between sliding tray 104 and the baffle 105 through the extrusion gasbag 106 of inflation, improve the gas tightness of equipment, in addition, utilize the flexible that electric telescopic handle 110 produced, the distance of hot plate 305 and support frame 301 receives electric telescopic handle 110 to change, when support frame 301 and hot plate 305 distance improve, the influence of the pulling force of extrusion pole 302 and clean horizontal pole 303 is close to 305 central point, accomplish the cleanness to hot plate 305 outer wall, avoid because the cover of hot plate 305 outer wall dust, influence the thermal conductivity of hot plate 305, when accomplishing the intensification and cooling, because there is great difference in temperature between equipment inside temperature and the outside temperature, when equipment inside temperature is high, equipment shell 101 can condense the water droplet in interior wall department, and the water droplet will be along the inner wall downwardly moving of condensation plate 103, and with extrusion plate 109 inner wall contact, finally with the moisture condensation and drip in equipment shell 101 inner wall, because extrusion plate 109 contacts with moisture in above-mentioned process, when later work, form the clearance between extrusion plate 109 and extrusion plate 108, will carry some and carry the dust can carry the part and get into the inside wall of equipment because of the inside temperature is big difference between the outside temperature, but the inside temperature is reduced, can be in addition, the dust can be reduced because the inside wall of the expansion plate 109, the dust is more is absorbed in the expansion and the equipment side wall is more than the inside wall is washed, the expansion plate 109, the dust is more than the inside can be washed, and the inside the expansion plate is washed, and the inside wall is washed, and the equipment is washed, and has been washed.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (8)

1. The utility model provides an information processing system based on big data, includes shell mechanism (1), shell mechanism (1) still includes equipment shell (101), the outer wall department fixedly connected with of equipment shell (101) collects swash plate (102), the inner wall department fixedly connected with condensation board (103) of collecting swash plate (102), its characterized in that still includes:

the sealing mechanism (2) comprises a first air box (201) fixedly connected to the side wall of the equipment shell (101), an extrusion long plate (202) is connected to the inner wall of the first air box (201) in a sliding mode, and a pushing column (203) is fixedly connected to the side wall of the extrusion long plate (202);

the control mechanism (3), control mechanism (3) are including fixed connection in support bracket (301) of collecting swash plate (102) outer wall department, the one end that collection swash plate (102) was kept away from to support bracket (301) rotates and is connected with squeeze lever (302), the one end that support bracket (301) was kept away from to squeeze lever (302) rotates and is connected with clean horizontal pole (303).

2. An information processing system based on big data as claimed in claim 1, wherein: the shell mechanism (1) further comprises a sliding groove (104) formed in the side wall of the equipment shell (101), a baffle (105) is connected to the inner wall of the sliding groove (104) in a sliding mode, and an extrusion air bag (106) is fixedly connected to the inner wall of the sliding groove (104).

3. An information processing system based on big data according to claim 2, wherein: the shell mechanism (1) further comprises a telescopic square tube (107) which is slidably connected to the inner wall of the collecting inclined plate (102), a limiting plate (108) is slidably connected to the inner wall of the telescopic square tube (107), an extruding plate (109) is slidably connected to the inner wall of the limiting plate (108), an electric telescopic rod (110) is fixedly connected to the side wall of the equipment shell (101), a pressing support (111) is fixedly connected to one end, far away from the equipment shell (101), of the electric telescopic rod (110), and one end, far away from the electric telescopic rod (110), of the pressing support (111) is fixedly connected with the side wall of the extruding plate (109).

4. A big data based information processing system according to claim 3, wherein: the sealing mechanism (2) further comprises a fixing plate (204) fixedly connected to the side wall of the pushing column (203), the bottom of the fixing plate (204) is fixedly connected with the outer wall of the pressing support (111), a one-way valve (205) is connected to the top of the first air box (201) in a penetrating mode, and an air conveying square tube (206) is connected to the top of the first air box (201) in a penetrating mode.

5. The big data based information processing system of claim 4, wherein: sealing mechanism (2) still include through connection at check valve two (207) of gas-supply side pipe (206) inner wall department, the outer wall department through connection of check valve two (207) has gas-supply pipe (208), one end through connection that check valve two (207) were kept away from to gas-supply pipe (208) has into trachea (209), the bottom of going into trachea (209) is through-connected with the top of extrusion gasbag (106).

6. An information handling system based on big data as defined in claim 5, wherein: the sealing mechanism (2) further comprises a first sliding rail (210) fixedly connected with the inner wall of the limiting plate (108), a cross (211) is slidably connected to the inner wall of the first sliding rail (210), a second sliding rail (212) is slidably connected to one end, far away from the first sliding rail (210), of the cross (211), a cleaning rod (213) is fixedly connected to the side wall of the cross (211), and the outer wall of the cleaning rod (213) is slidably connected with the outer wall of the extruding plate (109).

7. The big data based information processing system of claim 6, wherein: the control mechanism (3) further comprises a second air box (304) fixedly connected to the side wall of the limiting plate (108), one end, away from the limiting plate (108), of the second air box (304) is fixedly connected with a heating plate (305), and the side wall of the second air box (304) is in through connection with an air pressure tank (306).

8. The big data based information processing system of claim 7, wherein: the control mechanism (3) further comprises a pushing plate (307) which is connected to the inner wall of the air pressure tank (306) in a sliding mode, a control rod (308) is fixedly connected to the side wall of the pushing plate (307), and a limiting rod (309) is fixedly connected to one end, far away from the pushing plate (307), of the control rod (308).