CN115003110A

CN115003110A - Monitoring equipment applied to operation of network machine room

Info

Publication number: CN115003110A
Application number: CN202210591618.4A
Authority: CN
Inventors: 钟召旭
Original assignee: Guangzhou Dongping Network Technology Co ltd
Current assignee: Guangzhou Dongping Network Technology Co ltd
Priority date: 2022-05-27
Filing date: 2022-05-27
Publication date: 2022-09-02

Abstract

The invention discloses monitoring equipment applied to network machine room operation in the field of machine room monitoring, which comprises a smoke sensor and a temperature sensor, wherein the smoke sensor and the temperature sensor are both connected with a control module, and the control module is connected with a humidifying mechanism, a ventilation mechanism and an alarm mechanism; the control module has 4 working states; a 1: the control module controls the humidifying mechanism to work when the smoke sensor is triggered and the temperature sensor is not triggered; a 2: the control module controls the humidifying mechanism and the ventilation mechanism to work simultaneously when the smoke sensor is not triggered and the temperature sensor is triggered; a 3: the smoke sensor and the temperature sensor are triggered simultaneously, and the control module controls the humidifying mechanism to work and controls the alarm mechanism to give an alarm; a 4: the smoke sensor and the temperature sensor are not triggered, and the control module does not work. The invention can not only monitor the temperature and dust in the machine room, but also automatically cool and remove dust when the temperature and dust in the machine room reach the threshold value, thereby carrying out unmanned and intelligent monitoring.

Description

Monitoring equipment applied to operation of network machine room

Technical Field

The invention belongs to the field of machine room monitoring, and particularly relates to monitoring equipment applied to network machine room operation.

Background

Most of the past computer lab monitoring measures are based on manual patrol, however, the manual patrol mode has the problems of high labor intensity, high possibility of being influenced by severe weather and the like. Along with the continuous improvement of the monitoring requirements of the machine room system, unmanned and intelligent monitoring of the machine room is a future development trend. At present, strict requirements are placed on the physical environment of a network machine room, and the network machine room is serious in heat dissipation due to the fact that a large number of electronic components are arranged, and the temperature of the machine room needs to be strictly controlled; in addition, dust is inevitably contained in the air of the machine room, and the dust in the air not only seriously affects the heat dissipation performance of equipment in the machine room, so that the temperature of the equipment in the machine room is overhigh, and the components of the equipment are easily damaged. For example, when the mainboard is burned, the fan does not rotate, and the noise is very large. Also, since the dust contains moisture and corrosive substances, short circuits may be caused. Dust is accumulated too much in the machine room equipment, so that a good insulation effect can be achieved, and poor contact between contacts of the connector is directly caused. Therefore, in addition to controlling room temperature, it is very necessary to remove dust from the room data center. There is therefore a need to address the above-mentioned problems.

The invention provides monitoring equipment applied to operation of a network machine room, which not only can monitor the temperature and dust in the machine room, but also can automatically cool and remove dust when the temperature and dust in the machine room reach threshold values, and can carry out unmanned and intelligent monitoring. In addition, the temperature reduction of the invention mainly depends on the heat exchange of the external cold air, thereby saving energy.

Disclosure of Invention

The invention aims to provide monitoring equipment applied to operation of a network machine room, so as to solve the problem of the defects of the prior art in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a monitoring device applied to operation of a network machine room comprises a smoke sensor and a temperature sensor, wherein the smoke sensor and the temperature sensor are both connected with a control module, and the control module is connected with a humidifying mechanism, a ventilation mechanism and an alarm mechanism; the control module comprises 4 working states; a 1: the control module controls the humidifying mechanism to work when the smoke sensor is triggered and the temperature sensor is not triggered; a 2: the control module controls the humidifying mechanism and the ventilation mechanism to work simultaneously when the smoke sensor is not triggered and the temperature sensor is triggered; a 3: the smoke sensor and the temperature sensor are triggered simultaneously, and the control module controls the humidifying mechanism to work and controls the alarm mechanism to give an alarm; a 4: the smoke sensor and the temperature sensor are not triggered, and the control module does not work.

Preferably, the ventilation mechanism comprises an air suction pipeline and an air exhaust pipeline which are respectively arranged at two sides of the machine room, an air suction fan and a filter layer are arranged at the air suction pipeline, and granular activated carbon is arranged in the filter layer and used for filtering outside air; the machine room bottom plate is hollow, an exhaust fan is arranged below the machine room bottom plate, and the exhaust fan is communicated with an exhaust pipeline; outside air is guided into the air suction pipeline through the suction fan, filtered by the filter layer and then enters the machine room; then enters an exhaust pipeline through an exhaust fan at the bottom of the machine room and finally leaves the machine room.

Preferably, the filter layer is arranged on a circulating mechanism, and the circulating mechanism is used for enabling the granular activated carbon to circularly flow among the side walls on two sides of the machine room, the top surface of the machine room and the bottom surface of the machine room; the circulating mechanism comprises a first flow channel vertically arranged on the side wall of the machine room, and the filter layer is arranged on the first flow channel; the lower end and the upper end of the first flow channel are respectively connected with a second flow channel and a third flow channel which are obliquely arranged, and the second flow channel is connected with the third flow channel through a fourth flow channel which is vertically arranged; the fourth flow channel is a spiral feeding pipe and comprises a rotating shaft and a stranding cage blade; the granular activated carbon flows and circulates in the first flow channel, the second flow channel, the third flow channel and the fourth flow channel in sequence.

Preferably, the height of the upper end of the winch cage blade is higher than that of the upper end of the first flow channel, and the height of the lower end of the winch cage blade is lower than that of the lower end of the first flow channel; the second flow channel is of a ventilation structure, and the exhaust fan is arranged below the second flow channel; the rotating shaft is hollow, and the exhaust fan is communicated with the exhaust pipeline through the hollow rotating shaft; the top surface of the fourth flow channel is a filter plate.

Preferably, the humidifying mechanism is rotatably installed at the top end of the network room and comprises a mist humidifier.

Preferably, the humidifying mechanism further comprises a rotating shaft, and the mist humidifier is rotatably mounted on the top surface of the machine room through the rotating shaft; and a first gear is fixedly arranged on the rotating shaft and is connected with the driving unit.

Preferably, the drive unit is including setting up at first gear side and rather than the first rack of meshing, fixed mounting has the horizon bar on the first rack, open the sliding tray that has the level to set up on the horizon bar, slidable mounting has the slip post in the sliding tray, slip post fixed mounting is on the terminal surface of second gear, the second gear wheel rotates to be installed on the top surface of computer lab, links to each other with external drive power supply.

Preferably, the first gear is an incomplete gear, the first rack is arranged on two sides of the first gear, and the first rack drives the first gear to rotate continuously in a single direction when moving in a reciprocating manner.

Preferably, an opening plate is hinged to the bottom surface of the third flow passage and is positioned right above the rotating shaft; a guide post is fixedly mounted at the upper end of the rotating shaft, a jacking inclined block is slidably mounted on the guide post, and the jacking inclined block is used for jacking the opening plate upwards; an inclined plate is fixedly arranged on the first rack and connected with a bottom wedge surface of the jacking inclined block; and the first rack drives the jacking inclined block to reciprocate up and down through the inclined plate during reciprocating movement.

Preferably, the external driving power supply is a double-shaft motor, and one end of the double-shaft motor is in transmission connection with the second gear; the other end is connected with the rotating shaft in a transmission way.

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

1. the intelligent temperature and dust monitoring system can monitor the temperature and dust in the machine room, and can automatically cool and remove dust when the temperature and dust in the machine room reach threshold values, so that unmanned and intelligent monitoring is performed. In addition, the temperature reduction of the invention mainly depends on the heat exchange of the external cold air, thereby saving energy.

2. According to the invention, the filter layer is arranged in the air suction pipeline, and the activated carbon is placed in the filter layer and used for adsorbing dust, moisture and corrosive substances in the outside air, so that clean air is guided into the machine room to be cooled, and the damage of electrical elements is avoided. The granular activated carbon flows in the machine room, and not only can adsorb and filter outside air, but also can adsorb wetted dust and moisture accumulated at the bottom of the machine room while flowing, so that humidity balance in the machine room is maintained while dust removal is carried out.

3. The mist humidifier can assist the granular activated carbon in the third flow channel to flow out of the first flow channel while rotating. The opening plate is driven to be opened and closed continuously by the reciprocating movement of the first rack, and the granular activated carbon on the opening plate is pushed for a distance towards the direction of the first flow channel by the opening and closing of the opening plate, so that the granular activated carbon is helped to flow in the obliquely arranged third flow channel, and the activated carbon is prevented from being blocked.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a monitoring device applied to a network room;

FIG. 2 is a schematic structural view of a machine room of the present invention in a half-section;

FIG. 3 is an enlarged view of a portion A of FIG. 2 according to the present invention;

FIG. 4 is an enlarged partial view of portion B of FIG. 2 in accordance with the present invention;

FIG. 5 is an enlarged, fragmentary view of portion C of FIG. 2 in accordance with the present invention;

FIG. 6 is a schematic structural view of the machine room of the present invention with a top partially cut away;

FIG. 7 is an enlarged, fragmentary view of portion D of FIG. 6 in accordance with the present invention;

FIG. 8 is a schematic view of the third flow path and drive unit of the present invention;

fig. 9 is a schematic diagram of a monitoring device of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

11-air suction pipeline, 12-air exhaust pipeline, 13-suction fan, 14-filter layer, 15-air exhaust fan, 21-first flow channel, 22-second flow channel, 23-third flow channel, 24-fourth flow channel, 25-rotating shaft, 26-twisted cage blade, 27-filter plate, 31-mist humidifier, 32-rotating shaft, 33-first gear, 34-first rack, 35-horizontal rod, 36-sliding groove, 37-sliding column, 38-second gear, 39-external driving power supply, 41-opening plate, 42-guide column, 43-jacking inclined block and 44-inclined plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-9, the invention provides a monitoring device applied to the operation of a network machine room, which comprises a smoke sensor and a temperature sensor, wherein the smoke sensor and the temperature sensor are both connected with a control module, and the control module is connected with a humidifying mechanism, a ventilation mechanism and an alarm mechanism; the control module comprises 4 working states; a 1: the control module controls the humidifying mechanism to work when the smoke sensor is triggered and the temperature sensor is not triggered; a 2: the control module controls the humidifying mechanism and the ventilation mechanism to work simultaneously when the smoke sensor is not triggered and the temperature sensor is triggered; a 3: the smoke sensor and the temperature sensor are triggered simultaneously, and the control module controls the humidifying mechanism to work and controls the alarm mechanism to give an alarm; a 4: the smoke sensor and the temperature sensor are not triggered, and the control module does not work.

As shown in fig. 2 and 9, the monitoring device of the present invention includes a sensor disposed at the top end of the machine room. The sensor includes a smoke sensor and a temperature sensor. The smoke sensor is used for monitoring particulate matters in the machine room. When the dust in the machine room is too much, because a large number of cooling fans are arranged in the network machine room, the dust can fly in the machine room under the blowing of the cooling fans, so that the smoke sensor in the invention is triggered, the smoke sensor transmits a signal to the control module, and when the control module only receives the trigger signal of the smoke sensor, the humidification mechanism in the machine room is controlled to humidify, so that the dust flying in the machine room can be wetted and sink due to self gravity, fall on the ground of the machine room, remove dust from the machine room, avoid the dust from flying, avoid the dust from being blown into the interior of an electrical element by the cooling fans, influence the heat dissipation of the electrical element and possibly cause short circuit, and protect the normal operation of the electrical element. The temperature sensor of the invention is triggered when the temperature in the machine room is too high and reaches a specified threshold value. At the moment, when the smoke sensor is not triggered and the temperature sensor is triggered, the control module controls the ventilation mechanism to ventilate. It is worth mentioning that the invention is mostly placed in areas with lower average temperature, and the temperature is reduced by using cold air in the external environment. When the temperature is reduced, the humidifying mechanism still humidifies and assists in reducing the temperature. When the smoke sensor and the temperature sensor in the machine room are triggered simultaneously, the fact that fire disasters possibly happen to the machine room is meant, the control module needs to control the alarm mechanism to give an alarm to workers, the workers are allowed to conduct investigation, the fire disasters are avoided, the fire extinguishment is timely achieved, loss is reduced, the humidifying mechanism still works to assist in extinguishing the fire, the ventilation mechanism stops ventilation, and oxygen is prevented from being provided for a fire source. When neither the smoke sensor nor the temperature sensor is triggered, the temperature and the dust amount in the environment of the machine room are normal, and the control module does not work. The invention can not only monitor the temperature and dust in the machine room, but also automatically cool and remove dust when the temperature and dust in the machine room reach the threshold value, thereby carrying out unmanned and intelligent monitoring. In addition, the temperature reduction of the invention mainly depends on the heat exchange of the external cold air, thereby saving energy.

Preferably, the ventilation mechanism comprises an air suction pipeline 11 and an air exhaust pipeline 12 which are respectively arranged at two sides of the machine room, the air suction pipeline 11 is provided with an air suction fan 13 and a filter layer 14, and the filter layer 14 is internally provided with granular activated carbon for filtering outside air; the machine room bottom plate is hollow, an exhaust fan 15 is arranged below the machine room bottom plate, and the exhaust fan 15 is communicated with an exhaust pipeline 12; outside air is guided into the air suction pipeline 11 through the suction fan 13, and is filtered by the filter layer 14 and then enters the machine room; and then enters the exhaust pipeline 12 through the exhaust fan 15 at the bottom of the machine room, and finally leaves the machine room.

The invention utilizes the outside cold air to exchange heat to help the machine room to cool, thereby saving energy consumption. However, the external environment is complex, and the air may contain dust, moisture or corrosive substances, etc., and such air entering the machine room may damage electrical components, so as shown in fig. 2 and 3, in the present invention, a filter layer 14 is disposed in the air suction pipeline, and activated carbon is disposed in the filter layer 14 for adsorbing dust, moisture and corrosive substances in the external air, so as to ensure that clean air is introduced into the machine room for cooling, and prevent the electrical components from being damaged. As shown in fig. 2, when the ventilation mechanism of the present invention works, the outside air is introduced into the air suction duct 11 through the suction fan 13, and enters the machine room after being filtered by the filter layer 14; then enters the exhaust pipeline 12 through the exhaust fan 15 at the bottom of the machine room and finally leaves the machine room. The flowing mode ensures that the heat exchange time between the outside air and the air in the machine room is long, the heat exchange area is large, and the cooling is sufficient.

Preferably, the filter layer 14 is arranged on a circulating mechanism, and the circulating mechanism is used for enabling the granular activated carbon to circularly flow between two side walls of the machine room, the top surface of the machine room and the bottom surface of the machine room; the circulating mechanism comprises a first flow channel 21 vertically arranged on the side wall of the machine room, and the filter layer 14 is arranged on the first flow channel 21; the lower end and the upper end of the first flow channel 21 are respectively connected with a second flow channel 22 and a third flow channel 23 which are obliquely arranged, and the second flow channel 22 is connected with the third flow channel 23 through a fourth flow channel 24 which is vertically arranged; the fourth flow channel 24 is a spiral feeding pipe and comprises a rotating shaft 25 and a stranding cage blade 26; the granular activated carbon flows and circulates in the first flow path 21, the second flow path 22, the third flow path 23, and the fourth flow path 24 in sequence

Although the filter layer 14 of the present invention can filter moisture from the outside air, the moisture in the machine room may accumulate at the bottom of the machine room due to the existence of the humidifying mechanism in the machine room, and the machine room may have excessive humidity. Therefore, the granular activated carbon is arranged in the machine room to circularly flow. As shown in fig. 2 and 3, the granular activated carbon of the present invention flows in the first flow channel 21, and the granular activated carbon adsorbs and dehumidifies the passing outside air at the filter layer 14. At this time, the granular activated carbon flows in the first flow path 21 from the top to the bottom due to the influence of its own weight. As shown in fig. 2, the granular activated carbon enters the second flow channel 22 while flowing to the bottom of the first flow channel 21. Because the computer lab bottom plate is the fretwork form, exhaust fan 15's suction can make the dust that is drenched the subsidence by humidification mechanism pass second flow channel 22, and the existence of granule active carbon can adsorb the dust of drenching this moment, avoids the dust of drenching piling up in the computer lab bottom, and granule active carbon can adsorb the moisture of computer lab bottom simultaneously, maintains the humidity stability in the computer lab. As shown in FIG. 5, the granular activated carbon flows in the second flow path 22, which is obliquely arranged, into the fourth flow path 24, and the rotation of the rotary shaft 25 drives the rotation of the stranding cage blades 26, lifting the granular activated carbon to the top. As shown in fig. 6 and 8, the granular active particles at the top of the fourth flow channel 24 enter the obliquely arranged third flow channel 23, flow into the first flow channel 21 again through the bell mouth, and circulate. The granular activated carbon flows in the machine room, and not only can adsorb and filter outside air, but also can adsorb wetted dust and moisture accumulated at the bottom of the machine room while flowing, so that humidity balance in the machine room is maintained while dust removal is carried out.

Preferably, the height of the upper end of the winch cage blade 26 is higher than that of the upper end of the first flow channel 21, and the height of the lower end of the winch cage blade 26 is lower than that of the lower end of the first flow channel 21; the second flow passage 22 is a ventilation structure, and the exhaust fan 15 is arranged below the second flow passage 22; the rotating shaft 25 is hollow, and the exhaust fan 15 is communicated with the exhaust pipeline 12 through the hollow rotating shaft 25; the top surface of the fourth flow channel 24 is a filter plate 27.

Granular activated carbon may be saturated with adsorption as the operating time increases, and most of the adsorbed activated carbon is water and a small part is dust. In order to prolong the service life of granular activated carbon, it is necessary to continuously evaporate water from the activated carbon. As shown in fig. 5, the hollow rotary shaft 25 is provided not only to communicate the air in the machine room to the exhaust duct 12. Because cold air enters the machine room and hot air is exhausted during ventilation. When the hot air passes through the hollow rotary shaft 25, the hot air heats the activated carbon in the fourth flow path 24 to promote evaporation of moisture in the activated carbon, and the evaporated moisture exits the fourth flow path 24 through the filter plate 27 and enters the exhaust duct 12, as shown in fig. 8. In addition, water vapor evaporated by the activated carbon can carry away part of dust, so that the activated carbon can be adsorbed again, and the service life of the activated carbon is prolonged.

Preferably, the humidifying mechanism is rotatably installed at the top end of the network room and comprises a mist humidifier 31.

Preferably, the humidifying mechanism further comprises a rotating shaft 32, and the mist humidifier 31 is rotatably mounted on the top surface of the machine room through the rotating shaft 32; a first gear 33 is fixedly mounted on the rotating shaft 32, and the first gear 33 is connected with a driving unit.

As shown in fig. 4, the purpose of this arrangement is to increase the coverage of the mist humidifier 31 by using the centrifugal force generated when the mist humidifier 31 rotates.

Preferably, the driving unit includes a first rack 34 disposed beside the first gear 33 and engaged therewith, the first rack 34 is fixedly mounted with a horizontal bar 35, the horizontal bar 35 is opened with a sliding groove 36 horizontally disposed, a sliding column 37 is slidably mounted in the sliding groove 36, the sliding column 37 is fixedly mounted on the end surface of the second gear 38, and the second gear 38 is rotatably mounted on the top surface of the machine room and connected with an external driving power supply 39.

The present invention provides an embodiment for rotating the mist humidifier 31. As shown in fig. 8, the second gear 38 is driven by the external driving power source 39 to rotate, the second gear 38 rotates to drive the sliding post 37 on the pneumatic end surface to move circularly, the sliding post 37 is slidably mounted in the sliding groove 36 on the horizontal rod 35, so that the horizontal rod 35 is driven to reciprocate back and forth when the sliding post 37 rotates circularly, the horizontal rod 35 is fixedly mounted on the first rack 34, so that the first rack 34 reciprocates to drive the first gear 33 to reciprocate, and then the mist humidifier 31 is driven to reciprocate through the rotating shaft 32. At this time, the mist humidifier 31 is rotated in a reciprocating manner, and the centrifugal force is small while the rotation speed is changing in a reciprocating manner.

Preferably, the first gear 33 is an incomplete gear, the first rack 34 is disposed on two sides of the first gear 33, and the first rack 34 drives the first gear 33 to rotate continuously in one direction when reciprocating.

The present method provides an embodiment that allows the mist humidifier 31 to rotate continuously in one direction. As shown in fig. 8, the present invention makes the first gear 33 be an incomplete gear, and the first rack 34 is disposed on both sides of the first gear 33, and both sides are integrally connected. When the horizontal rod 35 drives the first rack 34 to rotate back and forth, the horizontal rod 35 drives the first rack 34 to move in a single direction, and only one side of the first rack 34 is meshed with the toothed part of the first gear 33 to drive the first gear 33 to rotate in a single direction; when the horizontal rod 35 drives the first rack 34 to move reversely, the toothed part of the first gear 33 rotates to the other side of the first rack 34, and the first rack 34 drives the first gear 33 to continue to rotate in one direction. Therefore, the mist humidifier 31 is continuously rotated in one direction, the rotation speed is stable, and the centrifugal force is large.

Preferably, an opening plate 41 is hinged on the bottom surface of the third flow channel 23, and the opening plate 41 is positioned right above the rotating shaft 32; a guide post 42 is fixedly installed at the upper end of the rotating shaft 32, a jacking inclined block 43 is installed on the guide post 42 in a sliding manner, and the jacking inclined block 43 is used for jacking the opening plate 41 upwards; an inclined plate 44 is fixedly mounted on the first rack 34, and the inclined plate 44 is connected with the bottom wedge surface of the jacking inclined block 43; when the first rack 34 reciprocates, the jack-up block 43 is driven by the swash plate 44 to reciprocate up and down.

The mist humidifier 31 of the present invention assists the granular activated carbon in the third flow path 23 to flow out to the first flow path 21 while rotating. As shown in fig. 4, 7, and 8, the first rack 34 reciprocates to rotate the mist humidifier 31. As the first rack 34 reciprocates, the swash plate 44 fixedly mounted on the first rack 34 also moves. When the inclined plate 44 reciprocates, the jacking inclined block 43 connected with the wedge surface is driven to reciprocate up and down, and the jacking inclined block 43 reciprocates up and down to repeatedly jack the opening plate 41 positioned above the jacking inclined block, so that the opening plate 41 is continuously opened and closed. When the opening plate 41 is opened and closed, the granular activated carbon on the opening plate 41 is pushed a distance in the direction of the first flow channel 21, thereby helping the granular activated carbon to flow in the obliquely arranged third flow channel 23 and avoiding the activated carbon from being blocked.

Preferably, the external driving power supply 39 is a double-shaft motor, and one end of the double-shaft motor is in transmission connection with the second gear 38; the other end is connected with a rotating shaft 25 in a transmission way. As shown in fig. 7 and 8, the flow of the whole activated carbon is determined by whether the winch blade 26 rotates; the invention links the rotation of the winch blade 26 and the reciprocating movement of the first rack 34, and the rotation and the reciprocating movement work simultaneously to assist the flow of the activated carbon and ensure the circular flow of the activated carbon.

Claims

1. The utility model provides a be applied to supervisory equipment of network computer lab operation which characterized in that: the device comprises a smoke sensor and a temperature sensor, wherein the smoke sensor and the temperature sensor are both connected with a control module, and the control module is connected with a humidifying mechanism, a ventilation mechanism and an alarm mechanism; the control module comprises 4 working states; a 1: the control module controls the humidifying mechanism to work when the smoke sensor is triggered and the temperature sensor is not triggered; a 2: the control module controls the humidifying mechanism and the ventilation mechanism to work simultaneously when the smoke sensor is not triggered and the temperature sensor is triggered; a 3: the smoke sensor and the temperature sensor are triggered simultaneously, and the control module controls the humidifying mechanism to work and controls the alarm mechanism to give an alarm; a 4: the smoke sensor and the temperature sensor are not triggered, and the control module does not work.

2. The monitoring device applied to the operation of the network machine room according to claim 1, wherein: the ventilation mechanism comprises an air suction pipeline (11) and an air exhaust pipeline (12) which are respectively arranged at two sides of the machine room, an air suction fan (13) and a filter layer (14) are arranged at the air suction pipeline (11), and granular activated carbon is arranged in the filter layer (14) and is used for filtering outside air; the machine room bottom plate is hollow, an exhaust fan (15) is arranged below the machine room bottom plate, and the exhaust fan (15) is communicated with an exhaust pipeline (12); outside air is guided into the air suction pipeline (11) through the suction fan (13), and enters the machine room after being filtered by the filter layer (14); then enters an exhaust pipeline (12) through an exhaust fan (15) at the bottom of the machine room and finally leaves the machine room.

3. The monitoring device applied to the operation of the network machine room according to claim 2, wherein: the filter layer (14) is arranged on a circulating mechanism, and the circulating mechanism is used for enabling granular activated carbon to circularly flow among the side walls of two sides of the machine room, the top surface of the machine room and the bottom surface of the machine room; the circulating mechanism comprises a first flow channel (21) vertically arranged on the side wall of the machine room, and the filter layer (14) is arranged on the first flow channel (21); the lower end and the upper end of the first flow channel (21) are respectively connected with a second flow channel (22) and a third flow channel (23) which are obliquely arranged, and the second flow channel (22) is connected with the third flow channel (23) through a fourth flow channel (24) which is vertically arranged; the fourth flow channel (24) is a spiral feeding pipe and comprises a rotating shaft (25) and a stranding cage blade (26); the granular activated carbon flows and circulates in the first flow channel (21), the second flow channel (22), the third flow channel (23), and the fourth flow channel (24) in sequence.

4. The monitoring device applied to the operation of the network machine room according to claim 3, wherein: the height of the upper end of the winch cage blade (26) is higher than that of the upper end of the first flow channel (21), and the height of the lower end of the winch cage blade (26) is lower than that of the lower end of the first flow channel (21); the second flow channel (22) is of a ventilation structure, and the exhaust fan (15) is arranged below the second flow channel (22); the rotating shaft (25) is hollow, and the exhaust fan (15) is communicated with the exhaust pipeline (12) through the hollow rotating shaft (25); the top surface of the fourth flow channel (24) is a filter plate (27).

5. The monitoring device applied to the operation of the network machine room according to claim 4, wherein: the humidifying mechanism is rotatably installed at the top end of the network machine room and comprises a mist humidifier (31).

6. The monitoring device applied to the operation of the network machine room according to claim 5, wherein: the humidifying mechanism further comprises a rotating shaft (32), and the mist humidifier (31) is rotatably installed on the top surface of the machine room through the rotating shaft (32); a first gear (33) is fixedly mounted on the rotating shaft (32), and the first gear (33) is connected with a driving unit.

7. The monitoring device applied to the operation of the network machine room according to claim 6, wherein: drive unit is including setting up first rack (34) at first gear (33) side and rather than meshing, fixed mounting has horizon bar (35) on first rack (34), open sliding tray (36) that have the level to set up on horizon bar (35), sliding tray (36) slidable mounting has slip post (37), slip post (37) fixed mounting is on the terminal surface of second gear (38), second gear (38) rotate to be installed on the top surface of computer lab, link to each other with external drive power supply (39).

8. The monitoring device applied to the operation of the network machine room according to claim 7, wherein: the first gear (33) is an incomplete gear, the first rack (34) is arranged on two sides of the first gear (33), and the first rack (34) drives the first gear (33) to rotate continuously in a single direction when moving in a reciprocating mode.

9. The monitoring device applied to the operation of the network machine room according to claim 8, wherein: an opening plate (41) is hinged to the bottom surface of the third flow channel (23), and the opening plate (41) is positioned right above the rotating shaft (32); a guide post (42) is fixedly mounted at the upper end of the rotating shaft (32), a jacking inclined block (43) is slidably mounted on the guide post (42), and the jacking inclined block (43) is used for jacking the opening plate (41) upwards; an inclined plate (44) is fixedly mounted on the first rack (34), and the inclined plate (44) is connected with a bottom surface wedge surface of the jacking inclined block (43); when the first rack (34) moves in a reciprocating manner, the jacking inclined block (43) is driven by the inclined plate (44) to move up and down in a reciprocating manner.

10. The monitoring device applied to the operation of the network machine room according to claim 9, wherein: the external driving power supply (39) is a double-shaft motor, and one end of the double-shaft motor is in transmission connection with the second gear (38); the other end is connected with a rotating shaft (25) in a transmission way.