CN115199879A - Communication power supply monitoring method and system based on Internet of things - Google Patents

Abstract

The invention provides a communication power supply monitoring system based on the Internet of things, which comprises a guide rail, a moving module, a connecting rod, a monitoring camera body, a sleeve, a rotating side strip and a driving rotating mechanism, wherein the guide rail is transversely arranged, a hollow cavity is formed in the middle of the guide rail, the moving module comprises a moving block connected to the bottom of the guide rail in a sliding mode and a moving mechanism which is rotatably installed on the inner wall of the hollow cavity and used for driving the moving block to move, the connecting rod is fixed in the middle of the lower surface of a moving base block, and the monitoring camera body is fixed at the bottom of the connecting rod; the movable rail camera cleaning device can automatically clean dust on the surface of the monitoring camera body at regular intervals in the process of moving monitoring, does not need manual cleaning, is time-saving and labor-saving, solves the problem of danger of ascending height in manual cleaning of the traditional rail camera, and improves the use safety.

Description

Communication power supply monitoring method and system based on Internet of things

Technical Field

The invention relates to the technical field of communication power supply monitoring devices, in particular to a communication power supply monitoring method and system based on the Internet of things.

Background

Communication power supply places usually on the communication power supply rack, and a plurality of racks are laid simultaneously and are inboard in a computer lab, and in order to guarantee that communication power supply's operating condition can be mastered by people in real time, can install communication power supply monitored control system in the computer lab inboard usually, this system utilizes internet of things to give cell-phone or computer terminal with control data transfer, and monitored control system contains two parts usually: communication power supply monitoring module and surveillance camera head. A communication power supply monitoring module is arranged on the communication power supply cabinet, the internal working condition of the communication power supply is monitored through the module, a monitoring camera monitors the working environment of the communication power supply in the machine room, and finally various data and pictures are transmitted to a computer or a mobile phone terminal in a monitoring person through transmission equipment;

and the surveillance camera head that adopts at the computer lab inboard is rail mounted surveillance camera head usually, rail mounted surveillance camera head is with the track mounting on the ceiling, the camera can remove along the track, thereby can accomplish the shooting work of the surveillance picture of a plurality of different positions through a camera, but rail mounted surveillance camera head can be infected with the dust on the surface of its camera after using for a certain time, the dust accumulation is more to cause the influence to the surveillance picture easily, reduce picture quality, current method is to accomplish the dust cleaning work on camera surface through artifical regular ascending height, and the very big human cost that has increased of artifical cleaning, and take trouble, it can accomplish cleaning work to need artifical climbing height simultaneously, certain danger has.

Therefore, there is a need to provide a new communication power monitoring method and system based on the internet of things to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the invention provides a communication power supply monitoring method and system based on the Internet of things.

The invention provides a communication power supply monitoring system based on the Internet of things, which comprises a guide rail, a moving module, a connecting rod, a monitoring camera body, a sleeve, a rotating side strip and a driving rotating mechanism, wherein the guide rail is transversely arranged, a hollow cavity is formed in the middle of the guide rail, the moving module comprises a moving block connected to the bottom of the guide rail in a sliding mode and a moving mechanism which is rotatably installed on the inner wall of the hollow cavity and used for driving the moving block to move, the connecting rod is fixed in the middle of the lower surface of a moving base block, the monitoring camera body is fixed at the bottom of the connecting rod, the sleeve is rotatably connected to the lower end of the outer wall of the connecting rod through a bearing, the rotating side strip is fixed on the outer wall of the sleeve, the upper end of the rotating side strip is arranged in an inverted L shape, the lower end of the rotating side strip is arranged in an arc shape, a sponge cleaning strip is fixed on the inner side of the lower end of the rotating side strip and is in extrusion contact with the outer wall of the monitoring camera body, and the driving rotating mechanism is fixed at the bottom of the guide rail and used for driving the sleeve to rotate to complete automatic cleaning work.

Preferably, the moving mechanism comprises a first rotating shaft, synchronous pulleys, a connecting block, a motor, a worm and a worm wheel, the two first rotating shafts are symmetrically connected to two ends of the inner wall of the hollow cavity through bearings, the synchronous pulleys are fixed to the middle of the outer wall of the first rotating shaft and are connected through synchronous belt transmission, the synchronous pulleys and the synchronous belts are located on the inner side of the hollow cavity, the connecting block is fixed to the top of the moving block, the upper end of the connecting block is fixed to the outer wall of the synchronous belts, the motor is fixed to one end of the outer wall of the guide rail, the worm is connected to one side, close to the motor, of the outer wall of the guide rail through the bearings in a rotating mode, the output end of the motor is fixed to the end of the worm, the worm wheel is fixed to the end, close to one first rotating shaft on one side of the worm, and the worm wheel is meshed with the worm.

Preferably, a housing is fixed on one side of the outer wall of the guide rail, which is close to the worm, and the worm wheel and the worm are both positioned on the inner side of the housing.

Preferably, the driving rotating mechanism comprises a rack, an upper end chamber, a speed reducer, a first gear, a driving wheel, a second rotating shaft, a grooved wheel, a driving gear and a driven gear, the rack is fixed on one side of the lower surface of the guide rail, the upper end chamber is formed at the upper end of the moving block, the top of the upper end chamber penetrates through the top of the moving block and extends to the top of the moving block, the rack is located on the inner side of the upper end chamber, the speed reducer is fixed on the inner wall of the upper end chamber, an output shaft of the speed reducer penetrates through the bottom of the moving block and extends to the bottom of the moving block, the output shaft of the speed reducer is rotatably connected with the side wall of the moving block through a bearing, the first gear is rotatably installed at the input end of the speed reducer through a one-way bearing, the first gear is meshed with the rack, the driving wheel is fixed at the bottom of the output shaft of the speed reducer, the second rotating shaft is rotatably connected to one side, the grooved wheel is fixed at the upper end of the second rotating shaft, the driving gear is matched with the lower end of the outer wall of the second rotating shaft, the driven gear is fixed at the middle of the outer wall of the sleeve, and the driven gear is meshed with the driving gear.

Preferably, the bottom of the moving block is located at the outer side of the connecting rod and the outer side of the second rotating shaft, and is fixed with a reinforcing ring, the upper end of the connecting rod is fixed with the inner wall of the reinforcing ring corresponding to the upper end of the connecting rod, and the upper end of the second rotating shaft is rotatably connected with the inner wall of the reinforcing ring corresponding to the upper end of the second rotating shaft.

Preferably, both sides of the upper end of the moving block are symmetrically fixed with side plates, the upper end of each side plate is rotatably connected with a roller through a shaft pin, and the four rollers are all in rolling connection with the outer wall of the guide rail.

Preferably, the both ends symmetry of guide rail is fixed with the mounting panel, and the mounting hole has been seted up to the top equidistance of mounting panel, and the mounting hole runs through the bottom that the mounting panel extended to the mounting panel.

Preferably, the bottom of the mounting plate is symmetrically fixed with reinforcing ribs, and one side of each reinforcing rib is fixed with the outer wall of the corresponding guide rail.

Preferably, the driving gear rotates for one circle to drive the driven gear to rotate for four circles.

The invention also provides a communication power supply monitoring method based on the Internet of things, which comprises the following steps:

1) The guide rail is installed on the ceiling in a hanging mode, and the monitoring camera body is driven to horizontally move along the guide rail to comprehensively monitor the communication power supply cabinet on the inner side of the machine room;

2) When the monitoring camera body works, the pictures of the communication power supply cabinet on the inner side of the machine room are shot through the monitoring camera body for monitoring, and meanwhile, the driving motor rotates to enable the monitoring camera body to reciprocate along the guide rail to monitor the communication power supplies on multiple positions on the inner side of the machine room;

3) And in the monitoring working process, the cleaning work of the surface of the monitoring camera body can be completed by driving the rotating mechanism to rotate the rotating side strips for one circle at certain intervals.

Compared with the related art, the communication power supply monitoring method and system based on the Internet of things have the following beneficial effects:

1. according to the invention, through the sleeve, the rotating side strip, the sponge cleaning strip and the driving rotating mechanism, the cleaning work of dust on the surface of the monitoring camera body can be regularly and automatically completed in the process of carrying out mobile monitoring on the monitoring camera, so that manual cleaning is not needed, manpower is saved, time and labor are saved, meanwhile, manual climbing cleaning is not needed, the problem of danger of climbing during manual cleaning of the traditional track camera is solved, and the use safety is improved.

2. The driving and rotating mechanism can utilize the power for driving the monitoring camera body to move to complete the work of driving the rotating side strips to rotate, and the cleaning work of the monitoring camera body can be completed without adding a power source, so that the operation and maintenance cost of the whole camera device is reduced to a certain extent.

Drawings

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

FIG. 2 is a schematic view of the sleeve position structure of the present invention;

FIG. 3 is an enlarged view of the invention at A;

FIG. 4 is a schematic structural diagram of a moving mechanism according to the present invention;

FIG. 5 is an enlarged view of the invention at B;

FIG. 6 is a schematic view of the position structure of the connecting block of the present invention;

FIG. 7 is a schematic structural diagram of a driving rotation mechanism according to the present invention;

FIG. 8 is an enlarged view of the invention at C;

FIG. 9 is a schematic view of the position of the decelerator according to the present invention;

FIG. 10 is a second schematic view of the driving rotation mechanism of the present invention;

FIG. 11 is a schematic diagram of the method of the present invention.

The reference numbers in the figures: 1. a guide rail; 1a, a hollow cavity; 2. a moving module; 21. a moving block; 22. a moving mechanism; 221. a first rotating shaft; 222. a synchronous pulley; 223. a synchronous belt; 224. connecting blocks; 225. a motor; 226. a worm; 227. a worm gear; 3. a connecting rod; 4. a monitoring camera body; 5. a sleeve; 6. rotating the side strips; 6a, sponge cleaning strips; 7. a drive rotation mechanism; 71. a rack; 72. an upper end chamber; 73. a speed reducer; 74. a first gear; 75. a drive wheel; 76. a second rotating shaft; 77. a grooved wheel; 78. a driving gear; 79. a driven gear; 8. a housing; 9. a reinforcing ring; 10. a side plate; 11. a roller; 12. mounting a plate; 12a, mounting holes; 13. and (5) reinforcing ribs.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

Referring to fig. 1, 2 and 3, an embodiment of the invention provides a communication power monitoring system based on the internet of things, which includes a guide rail 1, a moving module 2, a connecting rod 3, a monitoring camera body 4, a sleeve 5, a rotating side bar 6 and a driving rotating mechanism 7, wherein the guide rail 1 is transversely arranged, a hollow cavity 1a is formed in the middle of the guide rail 1, the moving module 2 includes a moving block 21 slidably connected to the bottom of the guide rail 1 and a moving mechanism 22 rotatably installed on the inner wall of the hollow cavity 1a and used for driving the moving block 21 to move, the connecting rod 3 is fixed in the middle of the lower surface of the moving base block, the monitoring camera body 4 is fixed at the bottom of the connecting rod 3, the sleeve 5 is rotatably connected to the lower end of the outer wall of the connecting rod 3 through a bearing, the rotating side bar 6 is fixed on the outer wall of the sleeve 5, the upper end of the rotating side bar 6 is arranged in an inverted L shape, the lower end of the rotating side bar 6 is arranged in an arc shape, a sponge cleaning bar 6a sponge 6a fixed on the inner side of the lower end of the rotating side bar 6, the sponge cleaning bar 6a squeezing contact with the outer wall of the monitoring camera body 4, the driving rotating mechanism 7 is fixed at the bottom of the guide rail 1 and used for driving the sleeve 5 to automatically cleaning work.

It should be noted that the communication power supply monitoring system based on the internet of things provided by the application can automatically complete the cleaning work of dust on the monitoring camera body 4 while ensuring the effective monitoring work of the communication power supply of the machine room, and does not need manual cleaning, thereby greatly saving manpower and greatly reducing the risk in the cleaning process.

Referring to fig. 4, 5 and 6, the moving mechanism 22 includes first rotating shafts 221, synchronous pulleys 222, connecting blocks 224, a motor 225, a worm 226 and a worm wheel 227, the two first rotating shafts 221 are symmetrically and rotatably connected to two ends of an inner wall of the hollow cavity 1a through bearings, the synchronous pulleys 222 are fixed to a middle portion of an outer wall of the first rotating shafts 221, the two synchronous pulleys 222 are in transmission connection through a synchronous belt 223, the synchronous pulleys 222 and the synchronous belt 223 are both located inside the hollow cavity 1a, the connecting block 224 is fixed to a top portion of the moving block 21, an upper end of the connecting block 224 is fixed to an outer wall of the synchronous belt 223, the motor 225 is fixed to one end of an outer wall of the guide rail 1, the worm 226 is rotatably connected to one side of the outer wall of the guide rail 1 close to the motor 225 through a bearing, an output end of the motor 225 is fixed to an end of the worm 226, the worm wheel 227 is fixed to an end of one first rotating shaft 221 inside the hollow cavity 1a close to one side of the worm 226, and the worm wheel 227 is in meshing connection with the worm 226.

After the guide rail 1 is installed on the working position, when the movement monitoring work is performed, the worm 226 is driven to rotate through the driving motor 225, the worm wheel 227 is driven to rotate, the first rotating shaft 221 is driven to rotate, the synchronous belt pulley 222 is driven to rotate, the moving block 21 is driven to slide along the guide rail 1 through the transmission of the synchronous belt 223, after the moving block 21 moves to the end portion of the guide rail 1, the driving motor 225 rotates in the reverse direction, the moving block 21 can be driven to move in the reverse direction, and finally the monitoring camera body 4 can move on the guide rail 1 in a reciprocating mode to complete the movement monitoring work.

Referring to fig. 1, an outer cover 8 is fixed on one side of the outer wall of the guide rail 1 close to the worm 226, and the worm wheel 227 and the worm 226 are both located on the inner side of the outer cover 8, so that the worm wheel 227 and the worm 226 can be covered, the meshing work of the two is protected, dust is prevented from falling at the connecting position of the two, and the work of the moving mechanism 22 is prevented from being affected.

Referring to fig. 3, 6, 7, 8, 9 and 10, the driving rotation mechanism 7 includes a rack 71, an upper chamber 72, a reducer 73, a first gear 74, a driving wheel 75, a second rotation shaft 76, a sheave 77, a driving gear 78 and a driven gear 79, the rack 71 is fixed on one side of the lower surface of the guide rail 1, the upper chamber 72 is formed on the upper end of the moving block 21, the top of the upper chamber 72 penetrates through the moving block 21 and extends to the top of the moving block 21, the rack 71 is located inside the upper chamber 72, the reducer 73 is fixed on the inner wall of the upper chamber 72, an output shaft of the reducer 73 penetrates through the moving block 21 and extends to the bottom of the moving block 21, the output shaft of the reducer 73 is rotatably connected with the side wall of the moving block 21 through a bearing, the first gear 74 is rotatably mounted at the input end of the reducer 73 through a one-way bearing, the first gear 74 is engaged with the rack 71, the driving wheel 75 is fixed on the bottom of the output shaft of the reducer 73, the second rotation shaft 76 is rotatably connected to one side of the bottom of the moving block 21 close to the driving wheel 75 through a bearing, the sheave 77 is fixed on the upper end of the second rotation shaft 76, the driving wheel 75, the driving gear 77, the driving gear 78, the outer wall of the driving gear 78 is engaged with the driving wheel 79, the outer wall of the sheave 79, and the driving gear 79, and the four-way gear 79 is rotatably connected with the driving gear 79, and the driving gear 79.

When the moving block 21 moves from one end of the guide rail 1 close to the motor 225 to one end far away from the motor 225, the rack 71 can toggle the first gear 74 to rotate, and because the first gear 74 is rotatably mounted on the input end of the speed reducer 73 through the one-way bearing, the rotating direction of the first gear 74 can drive the input end of the speed reducer 73 to rotate under the action of the one-way bearing, and when the moving block 21 moves from one end of the guide rail 1 far away from the motor 225 to one end close to the motor 225, the first gear 74 is driven by the rack 71 to rotate and cannot drive the input end of the speed reducer 73 to rotate under the action of the one-way bearing;

after the input end of the speed reducer 73 rotates, through the speed reduction effect of the speed reducer 73, after the input end of the speed reducer 73 rotates for a certain number of turns, the output end of the speed reducer 73 can rotate for one turn, so that the cleaning work can be performed at a long time interval, the output end of the speed reducer 73 rotates for one turn and can drive the driving wheel 75 to rotate for one turn, the driving wheel 75 rotates for one turn and drives the grooved wheel 77 to rotate for 90 degrees, as the grooved wheel 77 and the driving gear 78 are coaxially fixed on the second rotating shaft 76, the driving gear 78 also rotates for 90 degrees, and as the driving gear 78 rotates for one turn and drives the driven gear 79 to rotate for four turns, the driving gear 78 rotates for 90 degrees and drives the driven gear 79 to rotate for one turn and further can drive the sleeve 5 to rotate for one turn and drive the rotating side bar 6 to rotate for one turn, so that the sponge cleaning bar 6a wipes one turn on the outer wall of the monitoring camera body 4, one cleaning work can be jacked up in such a reciprocating manner and automatically, manual cleaning work is not needed, and manpower is saved.

Referring to fig. 3, the reinforcing rings 9 are fixed to the bottom of the moving block 21 and the outer side of the connecting rod 3 and the outer side of the second rotating shaft 76, the upper end of the connecting rod 3 is fixed to the inner wall of the reinforcing ring 9 corresponding to the upper end of the connecting rod, and the upper end of the second rotating shaft 76 is rotatably connected to the inner wall of the reinforcing ring 9 corresponding to the upper end of the connecting rod, so that the connection stability between the moving block 21 and the connecting rod 3 can be improved, and the connection stability between the second rotating shaft 76 and the moving block 21 can be improved.

Referring to fig. 1, the side plates 10 are symmetrically fixed to both sides of the upper end of the moving block 21, the upper ends of the side plates 10 are rotatably connected to the rollers 11 through the shaft pins, and the four rollers 11 are all in rolling connection with the outer wall of the guide rail 1, so that the moving block 21 can smoothly move along the guide rail 1.

Referring to fig. 1, mounting plates 12 are symmetrically fixed to two ends of a guide rail 1, mounting holes 12a are equidistantly formed in the top of the mounting plates 12, and the mounting holes 12a penetrate through the mounting plates 12 and extend to the bottom of the mounting plates 12, so that the guide rail 1 can be installed in an auxiliary manner.

Referring to fig. 1, the bottom of the mounting plate 12 is symmetrically fixed with the reinforcing ribs 13, and one side of each reinforcing rib 13 is fixed to the outer wall of the guide rail 1, so that the connection strength between the mounting plate 12 and the guide rail 1 is improved.

Referring to fig. 11, the present invention further provides a communication power monitoring method based on the internet of things, which includes the following steps:

1) The guide rail 1 is installed on a ceiling in a hanging mode, and the monitoring camera body 4 is driven to horizontally move along the guide rail 1, so that a communication power supply cabinet on the inner side of a machine room can be monitored comprehensively;

2) When the monitoring camera body 4 works, pictures of a communication power supply cabinet on the inner side of the machine room are shot through the monitoring camera body 4 for monitoring, and meanwhile, the driving motor 225 rotates to enable the monitoring camera body 4 to reciprocate along the guide rail 1 to monitor communication power supplies on multiple positions on the inner side of the machine room;

3) And in the monitoring working process, the cleaning work of the surface of the monitoring camera body 4 can be completed by driving the rotating side strip 6 to rotate for one circle through the driving rotating mechanism 7 at certain intervals

The circuits and controls involved in the present invention are all the prior art, and are not described herein in detail.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A communication power supply monitoring system based on the Internet of things is characterized by comprising:

the guide rail (1) is transversely arranged, and a hollow cavity (1 a) is formed in the middle of the guide rail (1);

the moving module (2) comprises a moving block (21) connected to the bottom of the guide rail (1) in a sliding mode and a moving mechanism (22) rotatably installed on the inner wall of the hollow cavity (1 a) and used for driving the moving block (21) to move;

the connecting rod (3), the said connecting rod (3) is fixed in the middle part of the lower surface of the movable base block;

the monitoring camera body (4), the monitoring camera body (4) is fixed at the bottom of the connecting rod (3);

the sleeve (5) is rotatably connected to the lower end of the outer wall of the connecting rod (3) through a bearing;

the monitoring camera comprises a rotating side strip (6), wherein the rotating side strip (6) is fixed on the outer wall of a sleeve (5), the upper end of the rotating side strip (6) is arranged in an inverted L shape, the lower end of the rotating side strip (6) is arranged in an arc shape, a sponge cleaning strip (6 a) is fixed on the inner side of the lower end of the rotating side strip (6), and the sponge cleaning strip (6 a) is in extrusion contact with the outer wall of a monitoring camera body (4);

and the driving rotating mechanism (7) is fixed at the bottom of the guide rail (1) and is used for driving the sleeve (5) to rotate to complete automatic cleaning.

2. The internet of things-based communication power monitoring system of claim 1, wherein the mobile mechanism (22) comprises:

the two first rotating shafts (221) are symmetrically and rotatably connected to two ends of the inner wall of the hollow cavity (1 a) through bearings;

the synchronous belt wheels (222) are fixed in the middle of the outer wall of the first rotating shaft (221), the two synchronous belt wheels (222) are in transmission connection through a synchronous belt (223), and the synchronous belt wheels (222) and the synchronous belt (223) are both located on the inner side of the hollow cavity (1 a);

the connecting block (224) is fixed to the top of the moving block (21), and the upper end of the connecting block (224) is fixed to the outer wall of the synchronous belt (223);

the motor (225), the said motor (225) is fixed to one end of the outer wall of the guide rail (1);

the worm (226) is rotatably connected to one side, close to the motor (225), of the outer wall of the guide rail (1) through a bearing, and the output end of the motor (225) is fixed with the end part of the worm (226);

the worm wheel (227) is fixed at the end part of a first rotating shaft (221) on one side, close to the worm (226), of the inner side of the hollow cavity (1 a), and the worm wheel (227) is meshed with the worm (226).

3. The communication power monitoring system based on the Internet of things of claim 2, wherein a housing (8) is fixed on one side, close to the worm (226), of the outer wall of the guide rail (1), and the worm wheel (227) and the worm (226) are both located on the inner side of the housing (8).

4. The internet of things-based communication power supply monitoring system according to claim 1, wherein the driving rotation mechanism (7) comprises:

the rack (71), the said rack (71) is fixed on one side of the lower surface of the guide rail (1);

the upper end chamber (72) is formed at the upper end of the moving block (21), the top of the upper end chamber (72) penetrates through the moving block (21) and extends to the top of the moving block (21), and the rack (71) is located on the inner side of the upper end chamber (72);

the speed reducer (73) is fixed on the inner wall of the upper end chamber (72), an output shaft of the speed reducer (73) penetrates through the moving block (21) and extends to the bottom of the moving block (21), and the output shaft of the speed reducer (73) is rotatably connected with the side wall of the moving block (21) through a bearing;

the first gear (74), the first gear (74) is rotatably mounted at the input end of the speed reducer (73) through a one-way bearing, and the first gear (74) is meshed with the rack (71);

the driving wheel (75), the said driving wheel (75) is fixed on the bottom of the output shaft of the speed reducer (73);

the second rotating shaft (76) is rotatably connected to one side, close to the driving wheel (75), of the bottom of the moving block (21) through a bearing;

the grooved wheel (77), the grooved wheel (77) is fixed on the upper end of the second rotating shaft (76), and the grooved wheel (77) is matched with the driving wheel (75);

the driving gear (78), the said driving gear (78) is fixed on the lower end of the outer wall of the second spindle (76);

the driven gear (79) is fixed in the middle of the outer wall of the sleeve (5), and the driven gear (79) is meshed with the driving gear (78).

5. The communication power supply monitoring system based on the internet of things as claimed in claim 4, wherein a reinforcing ring (9) is fixed to the bottom of the moving block (21) at the outer side of the connecting rod (3) and the outer side of the second rotating shaft (76), the upper end of the connecting rod (3) is fixed to the inner wall of the reinforcing ring (9) corresponding to the position of the connecting rod, and the upper end of the second rotating shaft (76) is rotatably connected to the inner wall of the reinforcing ring (9) corresponding to the position of the second rotating shaft.

6. The communication power monitoring system based on the internet of things of claim 1, wherein side plates (10) are symmetrically fixed to two sides of the upper end of the moving block (21), the upper ends of the side plates (10) are rotatably connected with rollers (11) through shaft pins, and the four rollers (11) are all in rolling connection with the outer wall of the guide rail (1).

7. The communication power monitoring system based on the Internet of things is characterized in that mounting plates (12) are symmetrically fixed to two ends of the guide rail (1), mounting holes (12 a) are formed in the top of each mounting plate (12) at equal intervals, and the mounting holes (12 a) penetrate through the mounting plates (12) and extend to the bottom of the mounting plates (12).

8. The communication power supply monitoring system based on the Internet of things of claim 7, wherein reinforcing ribs (13) are symmetrically fixed at the bottom of the mounting plate (12), and one side of each reinforcing rib (13) is fixed with the outer wall of the guide rail (1).

9. The Internet of things-based communication power supply monitoring system according to claim 4, wherein one rotation of the driving gear (78) drives the driven gear (79) to rotate four times.

10. A communication power supply monitoring method based on the Internet of things is characterized by comprising the following steps:

1) The guide rail (1) is installed on a ceiling in a hanging mode, and the driving monitoring camera body (4) is enabled to move horizontally along the guide rail (1) to comprehensively monitor a communication power supply cabinet on the inner side of a machine room;

2) When the monitoring camera is in operation, pictures of a communication power supply cabinet on the inner side of a machine room are shot through the monitoring camera body (4) for monitoring, and meanwhile, the driving motor (225) rotates to enable the monitoring camera body (4) to move in a reciprocating mode along the guide rail (1) to monitor communication power supplies on multiple positions on the inner side of the machine room;

3) And in the monitoring working process, the rotating side strips (6) can be driven to rotate by a circle through the driving rotating mechanism (7) at certain intervals to complete the cleaning work on the surface of the monitoring camera body (4).

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