CN114674368A - Power environment monitoring system - Google Patents

Abstract

The utility model relates to a power environment monitoring system, including test probe, the intelligent processing equipment who is coupled with test probe, the regulation and control equipment who is coupled with intelligent processing equipment, still include mobile intelligent monitoring device and supply mobile intelligent monitoring device slidable mounting's sliding guide, be equipped with drive arrangement on the mobile intelligent monitoring device, mobile intelligent monitoring device is equipped with fault factor test probe, fault factor test probe is coupled with mobile intelligent monitoring device, mobile intelligent monitoring device is used for sending corresponding trouble information according to the trouble index, mobile intelligent monitoring device and intelligent processing equipment wireless connection supply intelligent processing equipment to handle with trouble information transmission to intelligent processing equipment. The method and the device can monitor each server or power supply, and the monitoring accuracy is high; through setting up refrigeration passageway, cooling nozzle and feed through mechanism for this application can cool off overheated server, makes the server difficult because of the high impaired of temperature.

Description

Power environment monitoring system

Technical Field

The application relates to the technical field of intelligent monitoring, in particular to a power environment monitoring system.

Background

With the development and popularization of information technology, the number of computer systems and communication equipment is increasing day by day, and the scale is getting larger, and a central computer room, a computer system and a communication network become a core part of business management of each large unit. In order to ensure the safe and normal operation of the system, a machine room power system, an environmental system, a fire-fighting system and a security system which are matched with the system must work stably and coordinately at any time. If the power and environmental equipment of the machine room fails, the operation of the computer system is influenced slightly, and the computer and the communication equipment are scrapped seriously, so that the system is paralyzed, and the consequences are unreasonable. Therefore, it is necessary to monitor the power and environment system of the central machine room in real time. Thereby the dynamic environment monitoring system is pushed out. The system is used for continuously monitoring the environmental factors of the areas where the power equipment and the communication equipment are located, and the stability of the environment is maintained through the temperature regulating device and the humidity regulating device, so that the equipment in the areas can work normally.

In view of the above-mentioned related technologies, a general power environment monitoring system monitors the temperature of the whole machine room or a power room, but a plurality of servers or power supplies are usually arranged in an array in one machine room, and each server or power supply may have a fault to cause an excessive ambient temperature.

Disclosure of Invention

In order to timely monitor the fault phenomenon of a single server or a power supply, the application provides a dynamic environment monitoring system.

The application provides a dynamic environment monitoring system adopts following technical scheme:

a dynamic environment monitoring system comprises a detection probe, an intelligent processing device coupled with the detection probe, a regulating device coupled with the intelligent processing device, a mobile intelligent monitoring device and a sliding guide rail for the sliding installation of the mobile intelligent monitoring device, the sliding guide rail is arranged close to each server or power supply, the mobile intelligent monitoring device is provided with a driving device for driving the mobile intelligent monitoring device to slide along the length direction of the sliding guide rail, the mobile intelligent monitoring device is provided with a fault factor detection probe for detecting fault indexes, the fault factor detection probe is coupled with the mobile intelligent monitoring device, the mobile intelligent monitoring device is used for sending out corresponding fault information according to the fault index, and the mobile intelligent monitoring device is in wireless connection with the intelligent processing equipment so as to transmit the fault information to the intelligent processing equipment for the intelligent processing equipment to process.

Through adopting above-mentioned technical scheme, through setting up sliding guide and removing intelligent monitoring device, remove intelligent monitoring device and can follow sliding guide's length direction and remove to one side of every server to carry out fault detection to every server, and send the fault information who detects for intelligent processing equipment, so that this monitoring system can monitor every server, thereby in time monitor the fault phenomenon of single individual server or power.

Preferably, the fault factor detection probe comprises a temperature sensor and a sound sensor, and the temperature sensor and the sound sensor are both coupled with the mobile intelligent monitoring device.

Through adopting above-mentioned technical scheme, through detecting temperature and sound, the trouble of server can embody on producing heat and making a noise, just can know simply whether the server breaks down through detecting temperature and sound.

Preferably, the mobile intelligent monitoring device comprises a bearing part and a rotating part, the rotating part is rotatably connected to the top of the bearing part, a convex part used for approaching the server is arranged on the side wall of the rotating part, the temperature sensor and the sound sensor are both located on the convex part, and a rotating motor for driving the rotating part to rotate is arranged on the bearing part.

Through adopting above-mentioned technical scheme, the setting of rotation portion, this system of being convenient for adjusts temperature sensor, sound sensor's position according to the actual position of server, makes it and server can keep specific distance for the monitoring result is more accurate.

Preferably, be equipped with the refrigeration passageway in the sliding guide, the tip and the outside high-pressure coolant storage jar intercommunication of refrigeration passageway, sliding guide is equipped with the intercommunication mouth that is used for communicateing the external world, refrigeration passageway inner wall is equipped with the valve plate that is used for sealing the intercommunication mouth, the valve plate pastes with the inner wall of refrigeration passageway towards the lateral wall of intercommunication mouth mutually, the lateral wall that the valve plate deviates from the intercommunication mouth is connected with and supports tight spring, support tight spring and be used for supporting the valve plate tightly on the inner wall of refrigeration passageway, support tight spring's both ends respectively in valve plate and refrigeration passageway fixed connection, remove intelligent monitoring device and be equipped with the cooling spray tube, be used for communicateing the feed mechanism of cooling spray tube and refrigeration passageway, feed mechanism is coupled with removal intelligent monitoring device, the cooling spray tube is used for spraying air towards the server.

Through adopting above-mentioned technical scheme, remove intelligent monitoring device and can carry out urgent refrigeration to the server for server or power are difficult because of further generating heat and impaired before personnel arrive.

Preferably, the intercommunication mechanism includes the straight line driver that connecting pipe, drive connecting pipe go up and down, the upper end and the cooling spray tube intercommunication of connecting pipe, the slip setting of connecting pipe is in removing intelligent monitoring device, the lower tip of connecting pipe is used for the butt valve plate, the diameter of connecting pipe is less than the diameter of intercommunication mouth, the connecting pipe outer wall is equipped with and is used for the intercommunication mouth with the seal of external separation and the intercommunicating pore that communicates with the cooling spray tube, the intercommunicating pore is located the seal below.

Through adopting above-mentioned technical scheme, order about the connecting pipe through sharp driver and move down and prop open the valve plate for during high-pressure air conditioning gets into the clearance between connecting pipe and the intercommunication mouth inner wall, get into the intercommunication downthehole by this clearance again, by the cooling spray tube to the server blowout.

Preferably, the sealing part is slidably connected to the connecting pipe, the sliding direction of the sealing part is along the axial direction of the connecting pipe, the connecting pipe is fixedly provided with a supporting block which is used for supporting against the sealing part, and the supporting block is located above the sealing part.

Through adopting above-mentioned technical scheme, closing part sliding connection is on the connecting pipe for the closing part just can seal the intercommunication mouth when the valve plate supports to open, later along with the continuation of connecting pipe moves down, makes the closing part offset with supporting the piece, makes the connecting pipe can further sticis the closing part on sliding guide, and the reinforcing is sealed.

Preferably, the abutting block and the sealing part are both annular, and a sealing rubber layer for sealing a gap between the sealing part and the sliding guide rail is arranged on the bottom surface of the sealing part.

Through adopting above-mentioned technical scheme, the setting of sealing rubber layer makes the sealed further reinforcing of closing part and sliding guide.

Preferably, the tip of cooling spray tube articulates there is the shower nozzle, the articulated department of shower nozzle installs the torsional spring, the both ends of torsional spring are connected in shower nozzle and cooling spray tube respectively, shower nozzle and cooling spray tube intercommunication, the cooling spray tube is equipped with the embedding piece, be equipped with the swing arc groove that supplies embedding piece slip embedding in the shower nozzle, the circumference lateral wall of embedding piece pastes with the cell wall of swing arc groove mutually, the axis of swing arc groove coincides with the articulated shaft of shower nozzle, the tip of cooling spray tube will swing the arc groove and seal, the embedding piece is equipped with the inflation hole along the lateral wall of torsional spring elasticity direction of restoring to the throne, the inflation hole intercommunication cooling spray tube inner space, the cell wall of swing arc groove is equipped with the exhaust hole that communicates with the external world, is used for sealing the closure piece in exhaust hole, closure piece and swing arc groove's lateral wall sliding connection, the closure piece is equipped with and is used for offseting with the surface of embedding piece sliding direction in order to drive the gliding sand grip of closure piece, the sliding direction of sand grip and embedding piece is equipped with two, the embedding piece is located between two sand grips, the closure piece is equipped with the gas vent that is used for communicateing inflatable vent and exhaust hole.

Through adopting above-mentioned technical scheme for the cooling spray tube makes the shower nozzle can the luffing motion when carrying out the jet-propelled cooling to server or power, changes the spray direction, thereby makes and can be more abundant with each position of cold air spraying to server or power so that the cooling.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the method and the device can monitor each server or power supply, and the monitoring accuracy is high;

2. by arranging the refrigeration channel, the cooling spray pipe and the communication mechanism, the server cooling device can cool an overheated server, so that the server is not easy to be damaged due to overhigh temperature;

3. through swing arc groove, exhaust hole, closing plate for when cooling spray tube spouted system air conditioning, the shower nozzle can the luffing motion, made the position change that the server was spouted to the air conditioning, made the cooling to the server more abundant.

Drawings

Fig. 1 is an architecture diagram of an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a mobile intelligent monitoring device, a sliding guide rail, and a server according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of a mobile intelligent monitoring device according to an embodiment of the present application.

Fig. 4 is a schematic cross-sectional view of a mobile intelligent monitoring device and a sliding guide rail according to an embodiment of the present application.

FIG. 5 is a schematic structural view of the top of the cooling nozzle of an embodiment of the present application.

Fig. 6 is a schematic structural diagram of a showerhead according to an embodiment of the present application.

Description of reference numerals: 1. detecting a probe; 2. an intelligent processing device; 3. regulating and controlling equipment; 4. a mobile intelligent monitoring device; 41. a bearing part; 42. a rotating part; 43. a convex portion; 44. rotating the motor; 45. cooling the spray pipe; 5. a sliding guide rail; 51. a refrigeration channel; 52. a communication port; 53. a valve plate; 54. the spring is tightly propped; 6. a drive device; 7. a fault factor detection probe; 71. a temperature sensor; 72. a sound sensor; 8. a communicating mechanism; 81. a connecting pipe; 82. a linear actuator; 83. a communicating hole; 84. a resisting block; 85. a closing part; 86. a sealing rubber layer; 87. a connecting spring; 88. a bellows; 9. a spray head; 91. a torsion spring; 92. embedding a block; 93. swinging the arc groove; 94. an inflation hole; 95. an exhaust hole; 96. a sealing sheet; 97. a convex strip; 98. and (7) an exhaust port.

Detailed Description

The embodiment of the application discloses a dynamic environment monitoring system.

Referring to fig. 1 and 2, a dynamic environment monitoring system includes a detection probe 1, an intelligent processing device 2 coupled to the detection probe 1, a regulation and control device 3 coupled to the intelligent processing device 2, a mobile intelligent monitoring device 4, and a sliding guide rail 5 for slidably mounting the mobile intelligent monitoring device 4. The detection probe 1 comprises a temperature probe, a humidity probe, a voltage probe and a current probe to detect environmental information such as environmental temperature, humidity, real-time current and real-time voltage in the machine room, after the intelligent processing equipment 2 acquires the environmental information, the internal program of the intelligent processing equipment 2 can control the operation of the regulation and control equipment 3 according to the environmental information to maintain the temperature and the humidity of the machine room in a stable range, so that the equipment in the machine room can work stably. Wherein, the regulating and controlling device 3 comprises a temperature and humidity regulating and controlling device such as an air conditioner.

Server or power in the computer lab are 4 x 4 array settings, adopt the server in this embodiment, every server equidistance is arranged, other embodiment servers also can be the array of other quantity, sliding guide 5 winds around the server of each ranks and sets up, make sliding guide 5 can pass through the dead ahead of every server, mobile intelligent monitoring device 4 has intelligent processor for intelligent equipment is inside, this intelligent processor can be the computer, be equipped with drive self on mobile intelligent monitoring device 4 and follow the gliding drive arrangement 6 of 5 length direction of sliding guide, drive arrangement 6 equipment adopts the railcar, make mobile intelligent monitoring device 4 can follow sliding guide 5 and remove the dead ahead to arbitrary one server, monitor around the server with being close to the server.

The monitored fault indexes comprise sound and temperature, the two fault indexes are mainly monitored by a fault factor detection probe 7 arranged on the mobile intelligent monitoring device 4, the fault factor detection probe 7 comprises a temperature sensor 71 and a sound sensor 72, the temperature sensor 71 and the sound sensor 72 are both coupled with an intelligent processor in the mobile intelligent monitoring device 4 so as to convey detected information comprising the sound and the temperature to the mobile intelligent monitoring device 4, and therefore the mobile intelligent monitoring device 4 can judge whether a server has faults or not according to the sound and the temperature information and output corresponding fault information. For example, when the temperature at a characteristic distance of the server exceeds a preset temperature value in the mobile intelligent monitoring device 4, the server generates heat abnormally, and an internal circuit has a fault; if the noise of the characteristic distance of the server exceeds a preset decibel value in the mobile intelligent monitoring device 4, a fan or a circuit element in the server is indicated to be in fault;

referring to fig. 3 and 4, the mobile intelligent monitoring device 4 includes a bearing portion 41 and a rotating portion 42, and the intelligent processor is fixed in the rotating portion 42. Bearing part 41 is located rotation part 42 below, the railcar is just installed on bearing part 41, rotation part 42 rotates and connects at bearing part 41 top, rotation part 42's lateral wall is fixed with convex part 43, temperature sensor 71, sound sensor 72 all are located convex part 43, the fixed rotating electrical machines 44 that is equipped with on bearing part 41, rotating electrical machines 44 passes through belt pulley mechanism drive rotation part 42 and rotates, because sliding guide 5 is winding around the server of each ranks and sets up, after mobile intelligent monitoring device 4 moved to another rank, convex part 43 orientation can change. The rotating motor 44 can drive the rotating part 42 to rotate to make the convex part 43 face the server, so that the temperature sensor 71 and the sound sensor 72 are close to the server to perform close-range monitoring on the temperature and the generated sound of the server, and of course, the server can be directly attached to the server for performing contact monitoring. After the sound or temperature of any server is found to be abnormal, the mobile intelligent monitoring device 4 obtains corresponding fault information according to the fault index, the mobile intelligent monitoring device 4 sends the fault information to the intelligent processing equipment 2 through a wireless network, and the intelligent processing equipment 2 sends alarm information to an external control room to inform personnel to process the corresponding server.

Since the internal electrical components of the server are further damaged by overheating the server for a long time before the arrival of a person for maintenance, the temperature of the server needs to be reduced during the period, so that the temperature of the server is reduced and the server is not easily damaged by overhigh temperature. Therefore, the refrigeration channel 51 is arranged in the sliding guide rail 5, the end part of the refrigeration channel 51 is communicated with the external high-pressure coolant storage tank, so that the coolant can enter the refrigeration channel 51, and the coolant can adopt dry ice or liquid nitrogen.

Referring to fig. 3 and 4, the slide rail 5 is provided with a communication port 52 for communicating the outside with the cooling passage 51, and a plurality of communication ports 52 are provided corresponding to the servers. The communicating port 52 is located at the top of the sliding guide rail 5, the valve plate 53 is mounted on the inner wall of the refrigerating channel 51 in a sliding mode, the sliding direction of the valve plate 53 is in the vertical direction, the side wall, facing the communicating port 52, of the valve plate 53 is attached to the inner wall of the refrigerating channel 51 to seal the communicating port 52, the side wall, facing away from the communicating port 52, of the valve plate 53 is connected with the abutting spring 54, the abutting spring 54 has outward expanding elastic force, one end of the abutting spring 54 is fixedly connected with the valve plate 53, the other end of the abutting spring is connected with the inner wall of the refrigerating channel 51 in a sliding mode, and the elastic force direction of the abutting spring 54 is also in the vertical direction.

The mobile intelligent monitoring device 4 is provided with a cooling spray pipe 45 for spraying cold air towards the server and a communication mechanism 8 for communicating the cooling spray pipe 45 with a refrigeration channel 51, wherein the cooling spray pipe 45 is an inherent part of the rotating part 42, the axis of the cooling spray pipe 45 is coaxial with the rotating shaft of the rotating part 42, and the bottom end of the cooling spray pipe 45 is rotatably connected to the bearing part 41 and extends upwards to extend out of the top of the rotating part 42.

The communicating mechanism 8 comprises a connecting pipe 81 and a linear driver 82 for driving the connecting pipe 81 to ascend and descend, the upper end of the connecting pipe 81 is communicated with the cooling spray pipe 45 through a corrugated pipe 88, the bottom end of the corrugated pipe 88 is fixedly connected with the connecting pipe 81, the top end of the corrugated pipe is rotatably connected with the cooling spray pipe 45, the connecting pipe 81 is a hard pipe, the diameter of the connecting pipe 81 is smaller than that of the communicating port 52, the connecting pipe 81 is used for communicating the cooling spray pipe 45 and the refrigerating channel 51, the connecting pipe 81 is arranged in the mobile intelligent monitoring device 4 in a sliding mode, the lower end portion of the connecting pipe 81 can extend out of the bottom of the bearing portion 41 and the bottom of the driving device 6 to be abutted to the valve plate 53, and the valve plate 53 is pushed away from the inner wall of the refrigerating channel 51. In this embodiment, the linear actuator 82 is an electric cylinder, the linear actuator 82 is coupled to the intelligent processor in the mobile intelligent monitoring device 4, the linear actuator 82 is fixedly connected to the bearing portion 41, a piston rod of the linear actuator 82 is fixedly connected to the connecting pipe 81, so that the connecting pipe 81 can be driven by the linear actuator 82 to move up and down to make the end of the connecting pipe 81 extend out of the bottom of the bearing portion 41, the valve plate 53 is pressed against the inner wall of the refrigeration channel 51 by the bottom end of the connecting pipe 81, and cold air in the refrigeration channel 51 can enter the connecting pipe 81 through the communication port 52.

A closed portion 85 for blocking the communication port 52 from the outside and a communication hole 83 communicating with the cooling nozzle 45 are provided in a side wall of the connection pipe 81, and the communication hole 83 is located below the closed portion 85. The lower surface of the closing portion 85 is used to abut against the top surface of the slide rail 5 to block the communication port 52 from the outside, so that cool air can enter the communication hole 83 through the communication port 52 and is finally sprayed toward the server by the cooling spray pipe 45 to cool the server.

Referring to fig. 3 and 4, in addition, in order to further prevent the leakage of the cold air, the sealing portion 85 is slidably sleeved on the connecting pipe 81, the sliding direction of the sealing portion 85 is along the axial direction of the connecting pipe 81, the connecting pipe 81 is fixedly connected with a butting block 84 for butting against the sealing portion 85, and the butting block 84 is located above the sealing portion 85. The connecting pipe 81 is sleeved with a connecting spring 87, two ends of the connecting spring 87 are respectively fixedly connected with the abutting block 84 and the closed part 85, the abutting block 84 and the closed part 85 are both annular, two opposite side walls of the abutting block 84 and the closed part 85 are both provided with two annular grooves for the connecting spring 87 to be completely embedded in, and the bottom surface of the closed part 85 is provided with a sealing rubber layer 86. The seal rubber layer 86 enables the seal portion 85 to be closely attached to the slide rail 5, so that the cold air is not easily leaked.

Referring to fig. 3 and 5, in order to enable the cool air to be more uniformly sprayed onto the server, the upper end of the cooling spray pipe 45 is hinged to a spray head 9, the spray head 9 is communicated with the cooling spray pipe 45, an articulated shaft of the spray head 9 is along a horizontal direction, so that the spray head 9 can swing up and down, a torsion spring 91 is installed at the articulated position of the spray head 9, the axis of the torsion spring 91 is coaxial with the axis of the articulated shaft of the spray head 9, and two ends of the torsion spring 91 are respectively connected to the spray head 9 and the cooling spray pipe 45, so that the spray head 9 can automatically reset after swinging.

Referring to fig. 5 and 6, the cooling nozzle 45 is fixed with an embedded block 92, a swing arc groove 93 for the embedded block 92 to be slidably embedded is provided in the nozzle 9, an axis of the swing arc groove 93 coincides with a hinge shaft of the nozzle 9, and circumferential side walls of the embedded block 92 are attached to two groove walls in a width direction of the swing arc groove 93 to divide the swing arc groove 93 into two parts. When the nozzle 9 rotates, the embedded block 92 can slide in the swing arc groove 93, and a movable gap is formed between the embedded block 92 and two end walls of the swing arc groove 93 in the length direction. The tip of cooling spray tube 45 pastes mutually with the surface of shower nozzle 9 and seals swing arc groove 93, and embedding piece 92 is equipped with along the lateral wall of torsional spring 91 elasticity direction that resets and aerifys hole 94, aerifys hole 94 intercommunication cooling spray tube 45 inner space for the shower nozzle 9 can deviate from the elasticity direction removal of torsional spring 91, makes the spray angle of shower nozzle 9 move down, makes shower nozzle 9 can carry out all-round cooling to the server.

Referring to fig. 3 and 6, in order to enable the spray head 9 to automatically return after rotating, the wall of the swing arc groove 93 is provided with an air vent 95 communicating with the outside and a sealing sheet 96 for sealing the air vent 95. The vent hole 95 is used for communicating the space of the part of the swing arc groove 93 where the inflation hole 94 is located, the sealing piece 96 is in sliding connection with the side wall of the swing arc groove 93, and the surface of the sealing piece 96 is attached to the groove wall of the swing arc groove 93 so as to seal the vent hole 95. The side wall of the sealing piece 96 in the swing arc groove 93 is fixedly connected with two protruding strips 97 which are used for abutting against the surface of the embedding block 92 to drive the sealing piece 96 to slide, the protruding strips 97 are arranged at intervals along the sliding direction of the embedding block 92, and the two protruding strips 97 are respectively used for abutting against two side walls which are opposite to each other with the embedding block 92, so that the embedding block 92 can drive the sealing piece 96 to move. The sealing plate 96 is provided with an exhaust port 98 for communicating the exhaust hole 95, the swing arc groove 93 and the inflation hole 94. When the inflation hole 94 inflates the swing arc groove 93, make the shower nozzle 9 swing, after the embedded block 92 moves to the lower extreme of swing arc groove 93, the sand grip 97 is driven the closure piece 96 by the embedded block 92 butt and moves, make gas vent 98 and exhaust hole 95 intercommunication, outside exhaust makes the internal gas pressure of swing arc groove 93 reduce, later receive torsional spring 91's answer elasticity effect, the shower nozzle 9 is swung upward and is reset, move to the upper end of swing arc groove 93 until the embedded block 92, the embedded block 92 can offset with another sand grip 97 at the removal in-process, drive the closure piece 96 and reset, thereby stagger exhaust hole 95 and gas vent 98 again, closure piece 96 separation exhaust hole 95 once more, make shower nozzle 9 circulate the luffing motion and cool off with the server injection air from different angles and cool down in order to improve the cooling effect.

The implementation principle of the power environment monitoring system in the embodiment of the application is as follows: when the intelligent processing device 2 of the monitoring system monitors that the environmental temperature is too high, the intelligent processing device 2 controls the mobile intelligent monitoring device 4 to move along the length direction of the sliding guide rail 5, when the intelligent processing device passes through each server, the mobile intelligent monitoring device 4 rotates the convex part 43 to one side close to the server, the temperature and the noise of the server are detected, the data are transmitted to the mobile intelligent monitoring device 4, an intelligent processor in the mobile intelligent monitoring device 4 judges the indexes, if the detected actual temperature value exceeds a preset value, a fault is obtained, the mobile intelligent monitoring device 4 transmits fault information to the intelligent processing device 2 through a wireless network, when the server breaks down, the intelligent processing device 2 feeds back the fault information to personnel, the feedback mode can be alarm or prompt feedback, and then the mobile intelligent monitoring device 4 passes through the communication mechanism 8, the cooling spray pipe 45 is communicated with the refrigerating channel 51, so that the spray head 9 cools the abnormal server, and the server is prevented from being further damaged for subsequent treatment by personnel.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a dynamic environment monitoring system, includes test probe (1), intelligent processing equipment (2) that are coupled with test probe (1), regulation and control equipment (3) that are coupled with intelligent processing equipment (2), its characterized in that: also comprises a mobile intelligent monitoring device (4) and a sliding guide rail (5) for the sliding installation of the mobile intelligent monitoring device (4), the sliding guide rail (5) is arranged close to each server or power supply, the mobile intelligent monitoring device (4) is provided with a driving device (6) for driving the mobile intelligent monitoring device to slide along the length direction of the sliding guide rail (5), the mobile intelligent monitoring device (4) is provided with a fault factor detection probe (7) for detecting fault indexes, the fault factor detection probe (7) is coupled with the mobile intelligent monitoring device (4), the mobile intelligent monitoring device (4) is used for sending out corresponding fault information according to the fault indexes, the mobile intelligent monitoring device (4) is in wireless connection with the intelligent processing equipment (2) so as to transmit the fault information to the intelligent processing equipment (2) for the intelligent processing equipment (2) to process.

2. A dynamic environment monitoring system as claimed in claim 1, wherein: the fault factor detection probe (7) comprises a temperature sensor (71) and a sound sensor (72), and the temperature sensor (71) and the sound sensor (72) are both coupled with the mobile intelligent monitoring device (4).

3. A dynamic environment monitoring system as claimed in claim 2, wherein: remove intelligent monitoring device (4) including bearing part (41) and rotation portion (42), rotation portion (42) rotate to be connected at bearing part (41) top, the lateral wall of rotation portion (42) is equipped with convex part (43) that are used for approaching the server, temperature sensor (71), sound sensor (72) all are located convex part (43), be equipped with drive rotation portion (42) pivoted rotation motor (44) on bearing part (41).

4. A dynamic environment monitoring system as claimed in claim 1, wherein: a refrigeration channel (51) is arranged in the sliding guide rail (5), the end part of the refrigeration channel (51) is communicated with an external high-pressure coolant storage tank, a communication port (52) used for being communicated with the outside is arranged on the sliding guide rail (5), a valve plate (53) used for sealing the communication port (52) is arranged on the inner wall of the refrigeration channel (51), the side wall of the valve plate (53) facing to the communication port (52) is attached to the inner wall of the refrigeration channel (51), the side wall of the valve plate (53) departing from the communication port (52) is connected with a resisting spring (54), the resisting spring (54) is used for resisting the valve plate (53) tightly on the inner wall of the refrigeration channel (51), two ends of the resisting spring (54) are fixedly connected with the valve plate (53) and the refrigeration channel (51) respectively, the mobile intelligent monitoring device (4) is provided with a cooling spray pipe (45) and a communication mechanism (8) used for communicating the cooling spray pipe (45) with the refrigeration channel (51), the communicating mechanism (8) is coupled with the mobile intelligent monitoring device (4), and the cooling spray pipe (45) is used for spraying cold air towards the server.

5. The dynamic environment monitoring system of claim 4, wherein: the utility model discloses a valve plate, including cooling spray tube (45), the straight line driver (82) that intercommunication mechanism (8) go up and down including connecting pipe (81), drive connecting pipe (81), the upper end and the cooling spray tube (45) intercommunication of connecting pipe (81), the slip setting of connecting pipe (81) is in removing intelligent monitoring device (4), the lower tip of connecting pipe (81) is used for butt valve plate (53), the diameter of connecting pipe (81) is less than the diameter of intercommunication mouth (52), connecting pipe (81) outer wall is equipped with and is used for communicating mouth (52) and sealing (85) of external separation and intercommunicating pore (83) that communicate with cooling spray tube (45), intercommunicating pore (83) are located sealing (85) below.

6. A dynamic environment monitoring system as claimed in claim 5, wherein: the sealing part (85) is connected to the connecting pipe (81) in a sliding mode, the sliding direction of the sealing part (85) is along the axial direction of the connecting pipe (81), the connecting pipe (81) is fixedly provided with a propping block (84) used for propping against the sealing part (85), and the propping block (84) is located above the sealing part (85).

7. A dynamic environment monitoring system as claimed in claim 6, wherein: the abutting block (84) and the sealing part (85) are both annular, and a sealing rubber layer (86) for sealing a gap between the sealing part (85) and the sliding guide rail (5) is arranged on the bottom surface of the sealing part (85).

8. A dynamic environment monitoring system as claimed in claim 7, wherein: the tip of cooling spray tube (45) articulates there is shower nozzle (9), torsional spring (91) are installed to the articulated department of shower nozzle (9), the both ends of torsional spring (91) are connected in shower nozzle (9) and cooling spray tube (45) respectively, shower nozzle (9) and cooling spray tube (45) intercommunication, cooling spray tube (45) are equipped with embedding piece (92), be equipped with swing arc groove (93) that supply embedding piece (92) slip embedding in shower nozzle (9), the circumference lateral wall of embedding piece (92) pastes with the cell wall of swing arc groove (93), the axis of swing arc groove (93) and the articulated shaft coincidence of shower nozzle (9), the tip of cooling spray tube (45) will swing arc groove (93) and seal, embedding piece (92) are equipped with gas charging hole (94) along the lateral wall of torsional spring (91) elasticity direction that resets, gas charging hole (94) communicate cooling spray tube (45) inner space, the cell wall of swing arc groove (93) is equipped with exhaust hole (95) with external intercommunication, is used for sealing closed piece (96) of exhaust hole (95), closed piece (96) and the lateral wall sliding connection of swing arc groove (93), closed piece (96) are equipped with and are used for offseting in order to drive the gliding sand grip (97) of closed piece (96) with the surface of embedding piece (92) slip direction, sand grip (97) are equipped with two with the slip direction of embedding piece (92), embedding piece (92) are located between two sand grips (97), closed piece (96) are equipped with gas vent (98) that are used for communicateing gas charging hole (94) and exhaust hole (95).

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