CN114383020A - Mechanical equipment fault monitoring equipment and method based on big data - Google Patents

Abstract

The invention relates to the technical field of monitoring, and discloses a large-data-based mechanical equipment fault monitoring device and a method, which solve the problem that the monitoring equipment is fixedly installed and is exposed to be placed, so that the monitoring is easily influenced by dust and the service life of the monitoring equipment is influenced; through being provided with and placing box, standing groove, dust receiver, filter screen, mounting panel, a section of thick bamboo and camera body, be convenient for realize depositing the sealed of camera body, avoid the camera body to expose and place and receive the dust influence, the effectual life who prolongs the camera body.

Description

Mechanical equipment fault monitoring equipment and method based on big data

Technical Field

The invention belongs to the technical field of monitoring, and particularly relates to mechanical equipment fault monitoring equipment and a method based on big data.

Background

Mechanical equipment is various in types, when the mechanical equipment runs, some parts of the mechanical equipment even can perform mechanical motion in different forms, the mechanical equipment comprises a driving device, a speed changing device, a transmission device, a working device, a braking device, a protection device, a lubricating system, a cooling system and the like, and in industrial production, the mechanical equipment can have a fault problem after being used for a long time, so that the fault of the mechanical equipment needs to be monitored.

However, the existing monitoring is fixedly installed in the external environment, so that the monitoring is exposed, dust is accumulated on the monitoring surface after long-term use, and the service life of the monitoring is influenced by the dust.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides the mechanical equipment fault monitoring equipment and the method based on the big data, which have the advantages of stable work, convenient monitoring, dust prevention and ventilation.

In order to achieve the purpose, the invention provides the following technical scheme: a big data-based mechanical equipment fault monitoring device comprises a placing box body and a camera body, the bottom end of the outer side wall of the placing box body is symmetrically provided with a placing groove, the interior of the placing groove is movably connected with a dust containing box, the bottoms of the two sides of the placing box body are symmetrically connected with filter screens, a mounting plate is arranged above the placing box body, the middle position of the bottom end of the mounting plate is provided with a camera body, the two sides of the mounting plate are symmetrically connected with rotating cylinders, the two rotating cylinders are connected through a height adjusting mechanism, the two sides of the top end of the placing box body are symmetrically provided with rotating auxiliary parts, the interior of the placing box body is provided with a containing groove, the placing box body is symmetrically provided with grooves communicated with the containing groove, the inner wall of the containing groove is symmetrically provided with a first slotting and a second slotting which are positioned below the first slotting, the second open slot is communicated with the placing slot, the air blowing group is arranged inside the accommodating slot, and the suction groups are arranged inside the second open slot;

height adjusting mechanism includes transmission group and driver, the transmission group includes the spread groove, the bracing piece, the altitude mixture control pole, the inserting groove, the teeth of a cogwheel, a gear and driver, the both sides intermediate position of mounting panel is seted up to the spread groove symmetry, the one end of a rotation section of thick bamboo extends to the inside of spread groove, the bracing piece symmetry is installed in the inner bottom end of recess, the inside of a rotation section of thick bamboo has all alternate the altitude mixture control pole, altitude mixture control pole and rotation section of thick bamboo are connected through the bearing, the altitude mixture control pole is L shape structure, the inserting groove has been seted up to the bottom of altitude mixture control pole, the bracing piece extends to in the inserting groove, the impartial distance in both sides of two altitude mixture control poles is equipped with the teeth of a cogwheel, the outside cover of a rotation section of thick bamboo is equipped with the gear one of being connected with the rotation auxiliary member, connect through the driver between two altitude mixture control poles.

Preferably, the driver includes gear six, two axis of rotation one, two axis of rotation two, motor one, four belt pulleys one, two belt one and two gear two, two axis of rotation one are installed in the inner wall of accomodating the groove, two axis of rotation two are installed in the inner wall of recess, two axis of rotation one is gone up and all is equipped with gear six, two six meshing of gear are connected, two axis of rotation one and two axis of rotation two are gone up and all are equipped with belt pulley one, the one end and the output shaft of motor one of them axis of rotation one, two axis of rotation two are gone up and all are equipped with the gear two of being connected with the tooth meshing, lie in all through belt one and be connected between the belt pulley one of axis of rotation two.

Preferably, the middle position of the inner wall of the rotating cylinder is provided with an inserting rod, one end of the height adjusting rod is provided with a slot sleeved outside the inserting rod, clamping plates are symmetrically arranged on two sides of the rotating cylinder, and the inner wall of the connecting slot is provided with a clamping groove clamped with the clamping plates.

Preferably, the two sides of the placing box body are symmetrically provided with thread grooves which are sleeved outside the two grooves and connected with the filter screen.

Preferably, the rotation auxiliary part comprises an installation rod, a connecting shaft, a third gear, a second belt pulley and a rotating device, the installation rod is symmetrically installed at the top end of the box body, one side of the installation rod is rotatably connected with the connecting shaft, the third gear meshed with the first gear is arranged at one end of the connecting shaft, the second belt pulley is arranged on the connecting shaft, and the two second belt pulleys are connected through the rotating device.

Preferably, the rotating device comprises a through groove, a second motor, a rotating shaft, a third belt pulley and a second belt, the top end of the box body is symmetrically provided with the through groove communicated with the first groove, the second motor is installed on one side of the first groove, the output shaft of the second motor is provided with the rotating shaft connected with the inner wall of the first groove, the third belt pulley is symmetrically arranged on the rotating shaft, and the third belt pulley is connected with the second belt pulley through the second belt penetrating through the inside of the through groove.

Preferably, the group of blowing includes bevel gear one, fixing base, rotation seat, bevel gear two, blowing fan leaf and belt pulley four, and bevel gear one symmetry is installed on the rotation axis, all is equipped with the fixing base on the rotation axis, and the bottom of fixing base is rotated and is connected with and rotates the seat, and the symmetry is equipped with belt pulley four on the rotation axis, rotates the conical gear two that is equipped with on the seat and is connected with the meshing of bevel gear one, and the bottom of rotating the seat all is equipped with blowing fan leaf.

Preferably, the suction group includes connecting seat, pivot, suction fan leaf, belt pulley five, belt three and scraping piece, and the connecting seat is installed on the inner wall top of fluting two, and it is connected with the pivot to rotate on the connecting seat, and the one end of pivot is equipped with suction fan leaf, is equipped with belt pulley five in the pivot, is connected through belt pulley five between belt pulley five and the belt pulley four.

Preferably, the scraping piece comprises a sleeve joint seat and a brush plate, the other end of the rotating shaft is provided with the sleeve joint seat, and the sleeve joint seat is provided with the brush plate located on one side of the filter screen.

The invention also provides a method for monitoring the equipment fault based on the big data, which comprises the following steps:

s1: moving the device to a position to be detected, starting a first motor to rotate forwards, driving a first rotating shaft to rotate by the first motor, and driving a gear to rotate by the first rotating shaft;

s2: the other rotating shaft I rotates through the meshing connection of the two gears VI, and the rotating shaft II rotates through the connection relation between the belt pulley I and the belt I, so that the gear II is driven to rotate;

s3: the gear teeth drive the height adjusting rod to move upwards through the meshing relation of the gear II and the gear teeth, the height adjusting rod drives the mounting plate to move upwards through the rotating cylinder, the gear I is meshed with the gear III, and the camera body is moved to the outside of the placing box body;

s4: the first motor stops rotating, and the second motor rotates;

s5: the motor II drives the belt pulley III to rotate through the rotating shaft, the rotation of the belt pulley II is realized through the connection relation of the belt II, the belt pulley II drives the gear III to rotate through the connecting shaft, and then the gear III drives the rotating cylinder to rotate through the gear I;

s6: the rotating cylinder drives the camera body to rotate through the mounting plate, so that the camera body rotates by one hundred eighty degrees and is positioned above the mounting plate, and then the motor II is turned off, so that the monitoring process of the camera body on the equipment is realized;

s7: after the monitoring of the camera body is finished, dust is distributed on the surface of the camera body, and then the second motor is started to rotate;

s8: the motor II drives the rotating shaft and the belt pulley III to rotate, the belt pulley II rotates through the connection relation of the belt II, and the connecting shaft drives the gear III to rotate;

s9: through the meshing relationship of the third gear and the first gear, the rotating cylinder drives the mounting plate to rotate by one hundred eighty degrees, and then the mounting plate drives the camera body to rotate to the lower part of the mounting plate, and the second motor stops acting;

s10: when the rotating shaft is started to rotate reversely, the height adjusting rod can move downwards, the height adjusting rod drives the rotating cylinder to move downwards, the rotating cylinder drives the mounting plate to move downwards, and then the mounting plate drives the camera body to move into the accommodating groove, so that the mounting plate can seal the accommodating groove;

s11: starting a second motor, wherein the second motor drives a rotating shaft to rotate, the rotating shaft drives a belt pulley IV and a bevel gear I to rotate, the rotating shaft drives a fixed seat to rotate, and the fixed seat drives the bevel gear II and a rotating seat to rotate around the rotating shaft;

s12: the conical gear II is meshed with the conical gear II through meshing connection, so that the conical gear II rotates on the conical gear I, and the conical gear II drives the blowing fan blade to rotate;

s13: the fan blades blow the accommodating grooves, so that the camera body can be cooled, and dust on the surface of the camera body is blown up, and the dust is convenient to collect;

s14: the belt III is rotated through the rotation of the belt pulley IV, the belt III drives the belt pulley V to rotate, the belt pulley V drives the suction fan blades to rotate, the dust is sucked, and the dust enters the dust storage box through the second open groove and is collected;

s15: the pivot rotates and to drive cup joint seat and brush board rotation, realizes that the brush board is to the continuous scraping of filter screen surface, realizes the dust removal of filter screen, avoids the filter screen to block up and influence the ventilation performance of placing the box.

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

(1) in work, the camera body is convenient to realize sealed storage of the camera body by arranging the storage box body, the storage groove, the dust storage box, the filter screen, the mounting plate, the rotating cylinder and the camera body, the camera body is prevented from being influenced by dust due to exposed placement, the service life of the camera body is effectively prolonged, and meanwhile, the design of the blowing group and the suction group is matched, so that the blowing operation is effectively carried out on the camera body, and the dust removal efficiency of the camera body is improved; through the design of the height adjusting mechanism, the height adjustment of the camera body is convenient to realize, the monitoring operation of the camera body is convenient, and the working stability of the camera body is further improved;

(2) through the matching of the height adjusting mechanism and the rotation auxiliary piece, the camera body can rotate one hundred eighty degrees conveniently, and the camera body can be monitored conveniently;

(3) through the design of the through groove, the motor II, the rotating shaft, the belt pulley III and the belt II, power is effectively provided for the rotation of the camera body, and power is provided for the blowing operation of the blowing group, so that the heat dissipation of the camera body is realized, meanwhile, the dust on the surface of the camera body is conveniently discharged, and the later-stage suction work of the dust is facilitated;

(4) the design of connecting seat, pivot, suction fan leaf, belt pulley five, belt three and scraping piece is convenient for carry out the suction to the dust of placing the box inside, realizes avoiding the filter screen to block up the scraping of filter screen simultaneously, and the effectual ventilation performance who places the box that has improved, the effectual realization is to the protection of camera body.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

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

FIG. 2 is a schematic structural view of the storage case of the present invention;

FIG. 3 is a schematic external view of FIG. 1 according to the present invention;

FIG. 4 is a partial schematic view of the height adjustment mechanism of the present invention;

FIG. 5 is a schematic view showing a connection structure of the rotation assisting member, the rotator and the blowing group according to the present invention;

FIG. 6 is an enlarged schematic view of FIG. 1 at A according to the present invention;

FIG. 7 is a first block diagram of the method of the present invention;

FIG. 8 is a block diagram of the method of the present invention;

in the figure: 1. placing the box body; 2. a placement groove; 3. a dust storage box; 4. filtering with a screen; 5. mounting a plate; 6. a rotating cylinder; 7. a camera body; 8. a height adjustment mechanism; 9. a receiving groove; 10. a groove; 11. grooving I; 12. grooving II; 13. connecting grooves; 14. a support bar; 15. a height adjustment lever; 16. inserting grooves; 17. gear teeth; 18. a bearing; 19. a first gear; 20. rotating a first shaft; 21. a second rotating shaft; 22. a first motor; 23. a first belt pulley; 24. a first belt; 25. a second gear; 26. inserting a rod; 27. a slot; 28. mounting a rod; 29. a connecting shaft; 30. a third gear; 31. a second belt pulley; 32. a second motor; 33. a rotating shaft; 34. a third belt pulley; 35. a second belt; 36. a first conical gear; 37. a fixed seat; 38. a rotating seat; 39. a second bevel gear; 40. a blower blade; 41. a belt pulley IV; 42. a connecting seat; 43. a rotating shaft; 44. an intake fan blade; 45. a fifth belt pulley; 46. a third belt; 47. a socket joint seat; 48. brushing the board; 49. a thread groove.

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 derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the first embodiment, as shown in fig. 1 to 8, the present invention comprises a placing box 1 and a camera body 7, wherein a placing groove 2 is symmetrically formed at the bottom end of the outer side wall of the placing box 1, a dust containing box 3 is movably connected inside the placing groove 2, filter screens 4 are symmetrically connected to the bottoms of the two sides of the placing box 1, a mounting plate 5 is arranged above the placing box 1, the camera body 7 is arranged at the middle position of the bottom end of the mounting plate 5, rotating cylinders 6 are symmetrically connected to the two sides of the mounting plate 5, the two rotating cylinders 6 are connected through a height adjusting mechanism 8, rotation auxiliary members are symmetrically arranged at the two sides of the top end of the placing box 1, an accommodating groove 9 is formed inside the placing box 1, grooves 10 communicated with the accommodating groove 9 are symmetrically formed on the placing box 1, a first slot 11 and a second slot 12 located below the first slot 11 are symmetrically formed on the inner wall of the accommodating groove 9, and the second slot 12 is communicated with the placing groove 2, the inside of the accommodating groove 9 is provided with a blowing group, and the inside of the second open groove 12 is provided with a suction group;

the height adjusting mechanism 8 comprises a transmission set and a driver, the transmission set comprises a connecting groove 13, a supporting rod 14, a height adjusting rod 15, an inserting groove 16, gear teeth 17, a bearing 18, a first gear 19 and a driver, the connecting groove 13 is symmetrically arranged at the middle position of two sides of the mounting plate 5, one end of the rotating cylinder 6 extends to the inside of the connecting groove 13, the supporting rod 14 is symmetrically arranged at the inner bottom end of the groove 10, the height adjusting rod 15 penetrates through the inside of the rotating cylinder 6, the height adjusting rod 15 is connected with the rotating cylinder 6 through the bearing 18, the height adjusting rod 15 is of an L-shaped structure, the inserting groove 16 is arranged at the bottom end of the height adjusting rod 15, the supporting rod 14 extends into the inserting groove 16, the gear teeth 17 are arranged at equal distances at two sides of the two height adjusting rods 15, the first gear 19 connected with a rotating auxiliary part is sleeved outside the rotating cylinder 6, and the two height adjusting rods 15 are connected through the driver, an inserting rod 26 is arranged in the middle of the inner wall of the rotating cylinder 6, one end of the height adjusting rod 15 is provided with a slot 27 sleeved outside the inserting rod 26, clamping plates are symmetrically arranged on two sides of the rotating cylinder 6, a clamping groove clamped with the clamping plates is arranged on the inner wall of the connecting groove 13, and threaded grooves 49 sleeved outside the second slotting 12 and connected with the filter screen 4 are symmetrically arranged on two sides of the placing box body 1;

when camera body 7 needs to be used, because it is connected to rotate through bearing 18 between a rotation section of thick bamboo 6 and the altitude mixture control pole 15, it is connected with installation pole 28 through slot 27 between a rotation section of thick bamboo 6 and the altitude mixture control pole 15, simultaneously the cardboard on a rotation section of thick bamboo 6 and the draw-in groove joint of spread groove 13 inner wall, can realize the stable connection of a rotation section of thick bamboo 6 and mounting panel 5, and then it is convenient to bring for the altitude mixture control and the rotation of mounting panel 5, drive altitude mixture control pole 15 through the driver and move up, and make altitude mixture control pole 15 shift up in the outside of bracing piece 14, then altitude mixture control pole 15 drives mounting panel 5 through a rotation section of thick bamboo 6 and shifts up, and make mounting panel 5 drive camera body 7 move up, make camera body 7 break away from and place box 1, and then bring the convenience for the monitoring of camera body 7.

In the second embodiment, on the basis of the first embodiment, as shown in fig. 1 and 4, the driver includes a gear six, two rotating shafts one 20, two rotating shafts two 21, a motor one 22, four belt pulleys one 23, two belts one 24 and two gears two 25, the two rotating shafts one 20 are installed on the inner wall of the accommodating groove 9, the two rotating shafts two 21 are installed on the inner wall of the groove 10, the two rotating shafts one 20 are both provided with the gear six, the two gear six are in meshed connection, the two rotating shafts one 20 and the two rotating shafts two 21 are both provided with the belt pulleys one 23, one end of one rotating shaft one 20 is connected with the output shaft of the motor one 22, the two rotating shafts two 21 are both provided with the gear two 25 in meshed connection with the gear teeth 17, and the belt pulleys one 23 on the rotating shafts one 20 and the rotating shafts two 21 are both connected through the belt one 24;

by starting the motor I22 to rotate forwards, the motor I22 drives one of the rotating shafts I20 to rotate, the rotating shaft I20 drives one of the gears II to rotate, the other gear II can drive the other rotating shaft I20 to rotate through the meshing connection of the two gears II, so that the rotation of the two belt pulleys I23 is realized, further the other two belt pulleys I23 can rotate through the connection relation of the belt I24, the belt pulley I23 can drive the rotating shaft II 21 to rotate, the rotating shaft II 21 drives the gear II 25 to rotate, the gear II 25 can drive the height adjusting rod 15 to perform height adjustment through the meshing relation of the gear II 25 and the gear II 17, further the height adjusting rod 15 drives the rotating cylinder 6 to move, further the gear I19 on the rotating cylinder 6 is meshed with the gear III 30, the convenience is brought to the rotation of the mounting plate 5 in the later period, and the camera body 7 can be conveniently rotated to the upper part of the mounting plate 5 to perform monitoring operation, a section of thick bamboo 6 drives camera body 7 through mounting panel 5 simultaneously and carries out altitude mixture control, and camera body 7 of being convenient for monitors mechanical equipment, and when camera body 7 was out of work, the realization was to camera body 7 sealed protection simultaneously, and then reduced the influence of dust to camera body 7.

Third embodiment, on the basis of the first embodiment, as shown in fig. 1, 3, 4 and 5, the rotation auxiliary member includes a mounting rod 28, a connecting shaft 29, a third gear 30, a second pulley 31 and a rotator, the mounting rod 28 is symmetrically mounted on the top end of the placing case 1, one side of the mounting rod 28 is rotatably connected with the connecting shaft 29, one end of the connecting shaft 29 is provided with the third gear 30 engaged with the first gear 19, the connecting shaft 29 is provided with the second pulley 31, the two second pulleys 31 are connected through the rotator, the rotator includes a through slot, a second motor 32, a rotating shaft 33, a third pulley 34 and a second belt 35, the top end of the placing case 1 is symmetrically provided with the through slot communicated with the first slot 11, the second motor 32 is mounted on one side of the first slot 11, the output shaft of the second motor 32 is provided with the rotating shaft 33 connected with the inner wall of the first slot 11, the rotating shaft 33 is symmetrically provided with the third pulley 34, the third belt pulley 34 is connected with the second belt pulley 31 through a second belt 35 penetrating through the through groove;

through the second motor 32, the second motor 32 drives the rotation axis 33 to rotate, the rotation axis 33 can drive the third belt pulley 34 to rotate, the connection relationship through the second belt 35 can make the second belt pulley 31 rotate, the second belt pulley 31 drives the connecting shaft 29 to rotate, the connecting shaft 29 drives the third gear 30 to rotate, through the meshing relationship of the third gear 30 and the first gear 19, can make the first gear 19 drive and rotate the barrel 6 to rotate, and then through the connection relationship of the cardboard on the barrel 6 and the inside draw-in groove of the connecting groove 13, can make the barrel 6 drive the mounting panel 5 to rotate one hundred eighty degrees, make the camera body 7 up, and then make things convenient for the camera body 7 to monitor the operation, close the second motor 32 simultaneously, the effectual job stabilization nature that has improved the camera body 7.

Fourth embodiment, based on the first embodiment, as shown in fig. 1, 5 and 6, the blowing unit includes a first bevel gear 36, a fixed seat 37, a rotating seat 38, a second bevel gear 39, a blowing fan blade 40 and a fourth belt pulley 41, the first bevel gear 36 is symmetrically installed on the rotating shaft 33, the rotating shaft 33 is provided with the fixed seat 37, the bottom end of the fixed seat 37 is rotatably connected with the rotating seat 38, the rotating shaft 33 is symmetrically provided with the fourth belt pulley 41, the rotating seat 38 is provided with the second bevel gear 39 engaged with the first bevel gear 36, the bottom end of the rotating seat 38 is provided with the blowing fan blade 40, the suction unit includes a connecting seat 42, a rotating shaft 43, a blowing fan blade 44, a fifth belt pulley 45, a third belt 46 and a scraping member, the connecting seat 42 is installed at the top end of the inner wall of the second slotted gear 12, the connecting seat 42 is rotatably connected with the rotating shaft 43, one end of the rotating shaft 43 is provided with the blowing fan blade 44, the rotating shaft 43 is provided with the fifth belt 45, the fifth belt pulley 45 is connected with the fourth belt pulley 41 through the fifth belt pulley 45, the scraping piece comprises a sleeving seat 47 and a brush plate 48, the sleeving seat 47 is arranged at the other end of the rotating shaft 43, and the brush plate 48 positioned on one side of the filter screen 4 is arranged on the sleeving seat 47;

when the camera body 7 is monitored, dust is distributed on the surface of the camera body 7, when the camera body 7 does not work, the second motor 32 is started to rotate, the second motor 32 drives the rotating shaft 33 and the third belt pulley 34 to rotate, the second belt pulley 31 is rotated through the connection relation of the second belt 35, the third gear 30 is driven to rotate through the connecting shaft 29, the rotating cylinder 6 drives the mounting plate 5 to rotate by one hundred eighty degrees through the meshing relation of the third gear 30 and the first gear 19, the mounting plate 5 drives the camera body 7 to rotate to the lower side of the mounting plate 5, the second motor 32 stops acting, the first rotating shaft 20 is started to rotate reversely, the height adjusting rod 15 is driven to move downwards, the height adjusting rod 15 drives the rotating cylinder 6 to move downwards, the rotating cylinder 6 drives the mounting plate 5 to move downwards, and the mounting plate 5 drives the camera body 7 to move into the accommodating groove 9, meanwhile, the mounting plate 5 seals the accommodating groove 9, then the second motor 32 is started, the second motor 32 drives the rotating shaft 33 to rotate, the rotating shaft 33 drives the belt pulley fourth 41 and the bevel gear first 36 to rotate, the rotating shaft 33 drives the fixing seat 37 to rotate, the fixing seat 37 drives the bevel gear second 39 and the rotating seat 38 to rotate around the rotating shaft 33, as the bevel gear first 36 is meshed with the bevel gear second 39, the bevel gear second 39 can rotate on the bevel gear first 36, the bevel gear second 39 can drive the blowing fan blade 40 to rotate, and the blowing fan blade 40 performs blowing operation on the accommodating groove 9, so that heat can be dissipated for the camera body 7, dust on the surface of the camera body 7 can be blown up, then the belt pulley fourth 41 can drive the belt third 46 to rotate, the belt third 46 can drive the belt pulley fifth 45 to rotate, and the belt fifth 45 drives the suction fan blade 44 to rotate, the realization is to the suction of dust, and then be convenient for make the dust collect in getting into dust receiver 3 through two 12 fluting, pivot 43 rotates simultaneously and can drive cup joint seat 47 and brush board 48 rotatory, realize the continuous scraping in brush board 48 surface to filter screen 4, realize filter screen 4's dust removal operation, avoid filter screen 4 to block up and influence the ventilation performance of placing box 1, and then realize the protection to camera body 7, the effectual life who prolongs camera body 7.

The method for monitoring the equipment based on the big data mechanical equipment fault comprises the following steps:

s1: moving the device to a position to be detected, starting a first motor 22 to rotate forwards, driving a first rotating shaft 20 to rotate by the first motor 22, and driving a sixth gear to rotate by the first rotating shaft 20;

s2: the other rotating shaft I20 is rotated through the meshing connection of the two gears II, and the rotating shaft II 21 is rotated through the connection relation of the belt pulley I23 and the belt I24, so that the gear II 25 is driven to rotate;

s3: the gear teeth 17 drive the height adjusting rod 15 to move upwards through the meshing relationship between the gear teeth 17 and the gear teeth 25, the height adjusting rod 15 drives the mounting plate 5 to move upwards through the rotating cylinder 6, the gear teeth 19 are meshed with the gear teeth 30, and the camera body 7 is moved to the outside of the placing box body 1;

s4: the first motor 22 stops rotating, and the second motor 32 rotates;

s5: the second motor 32 drives the third belt pulley 34 to rotate through the rotating shaft 33, the second belt pulley 31 rotates through the connection relation of the second belt 35, the second belt pulley 31 drives the third gear 30 to rotate through the connecting shaft 29, and then the third gear 30 drives the rotating cylinder 6 to rotate through the first gear 19;

s6: the rotating cylinder 6 drives the camera body 7 to rotate through the mounting plate 5, so that the camera body 7 rotates one hundred eighty degrees and is positioned above the mounting plate 5, and then the second motor 32 is turned off, so that the monitoring process of the camera body 7 on the equipment is realized;

s7: after the monitoring of the camera body 7 is completed, dust is distributed on the surface of the camera body 7, and then the second motor 32 is started to rotate;

s8: the second motor 32 drives the rotating shaft 33 and the third belt pulley 34 to rotate, the second belt pulley 31 rotates through the connection relation of the second belt 35, and the connecting shaft 29 drives the third gear 30 to rotate;

s9: through the meshing relationship of the third gear 30 and the first gear 19, the rotating cylinder 6 drives the mounting plate 5 to rotate by one hundred eighty degrees, the mounting plate 5 drives the camera body 7 to rotate to the position below the mounting plate 5, and the second motor 32 stops operating;

s10: when the first rotating shaft 20 is started to rotate reversely, the height adjusting rod 15 moves downwards, the height adjusting rod 15 drives the rotating cylinder 6 to move downwards, the rotating cylinder 6 drives the mounting plate 5 to move downwards, and then the mounting plate 5 drives the camera body 7 to move into the accommodating groove 9, so that the mounting plate 5 seals the accommodating groove 9;

s11: starting a second motor 32, wherein the second motor 32 drives a rotating shaft 33 to rotate, the rotating shaft 33 drives a fourth belt pulley 41 and a first bevel gear 36 to rotate, the rotating shaft 33 drives a fixed seat 37 to rotate, and the fixed seat 37 drives a second bevel gear 39 and a rotating seat 38 to rotate around the rotating shaft 33;

s12: the first bevel gear 36 is meshed with the second bevel gear 39, so that the second bevel gear 39 rotates on the first bevel gear 36, and the second bevel gear 39 drives the blowing fan blade 40 to rotate;

s13: the air blowing fan blade 40 blows air to the accommodating groove 9, can radiate heat of the camera body 7, blows dust on the surface of the camera body 7, and is convenient for dust collection;

s14: the belt III 46 rotates through the rotation of the belt pulley IV 41, the belt III 46 can drive the belt pulley V45 to rotate, the belt pulley V45 drives the suction fan blades 44 to rotate, the dust is sucked, and the dust enters the dust storage box 3 through the second slot 12 to be collected;

s15: the pivot 43 rotates and can drive socket 47 and brush board 48 rotatory, realizes that brush board 48 constantly scrapes the filter screen 4 surface, realizes filter screen 4's dust removal, avoids filter screen 4 to block up and influence the ventilation performance of placing box 1.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a mechanical equipment trouble supervisory equipment based on big data, is including placing box (1) and camera body (7), its characterized in that: the dust collecting box is characterized in that a placing groove (2) is symmetrically formed in the bottom end of the outer side wall of the placing box body (1), a dust collecting box (3) is movably connected inside the placing groove (2), filter screens (4) are symmetrically connected to the bottoms of the two sides of the placing box body (1), a mounting plate (5) is arranged above the placing box body (1), a camera body (7) is arranged in the middle of the bottom end of the mounting plate (5), rotating cylinders (6) are symmetrically connected to the two sides of the mounting plate (5), the two rotating cylinders (6) are connected through a height adjusting mechanism (8), rotating auxiliary pieces are symmetrically arranged on the two sides of the top end of the placing box body (1), a containing groove (9) is formed in the placing box body (1), grooves (10) communicated with the containing groove (9) are symmetrically formed in the placing box body (1), a first groove (11) and a second groove (12) located below the first groove (11) are symmetrically formed in the inner wall of the containing groove (9), the second open slot (12) is communicated with the placing slot (2), the air blowing group is arranged inside the accommodating slot (9), and the suction groups are arranged inside the second open slot (12);

the height adjusting mechanism (8) comprises a transmission set and a driver, the transmission set comprises a connecting groove (13), a supporting rod (14), a height adjusting rod (15), an inserting groove (16), gear teeth (17), a bearing (18), a first gear (19) and a driver, the connecting groove (13) is symmetrically arranged at the middle positions of two sides of the mounting plate (5), one end of the rotating cylinder (6) extends to the inside of the connecting groove (13), the supporting rod (14) is symmetrically arranged at the inner bottom end of the groove (10), the height adjusting rod (15) is inserted in the rotating cylinder (6), the height adjusting rod (15) is connected with the rotating cylinder (6) through the bearing (18), the height adjusting rod (15) is of an L-shaped structure, the inserting groove (16) is formed in the bottom end of the height adjusting rod (15), the supporting rod (14) extends to the inserting groove (16), the gear teeth (17) are arranged at equal distances of two sides of the two height adjusting rods (15), the outer part of the rotating cylinder (6) is sleeved with a first gear (19) connected with a rotating auxiliary part, and the two height adjusting rods (15) are connected through a driver.

2. The big data based mechanical equipment fault monitoring device as claimed in claim 1, wherein: the driver comprises a gear six, two rotating shafts one (20), two rotating shafts two (21), a motor one (22), four belt pulleys one (23), two belts one (24) and two gears two (25), wherein the two rotating shafts one (20) are arranged on the inner wall of the accommodating groove (9), the two rotating shafts two (21) are arranged on the inner wall of the groove (10), the two rotating shafts one (20) are respectively provided with the gear six, the two gears six are meshed and connected, the two rotating shafts one (20) and the two rotating shafts two (21) are respectively provided with the belt pulleys one (23), one end of one rotating shaft I (20) is connected with an output shaft of a motor I (22), two rotating shafts II (21) are respectively provided with a gear II (25) which is meshed with the gear teeth (17) and connected with the gear teeth, and belt pulleys I (23) positioned on the rotating shafts I (20) and the rotating shafts II (21) are connected through a belt I (24).

3. The big data based mechanical equipment fault monitoring device as claimed in claim 1, wherein: an inserting rod (26) is arranged in the middle of the inner wall of the rotating cylinder (6), one end of the height adjusting rod (15) is provided with a slot (27) which is sleeved outside the inserting rod (26), clamping plates are symmetrically arranged on two sides of the rotating cylinder (6), and clamping grooves clamped with the clamping plates are formed in the inner wall of the connecting groove (13).

4. The big data based mechanical equipment fault monitoring device as claimed in claim 1, wherein: the two sides of the placing box body (1) are symmetrically provided with thread grooves (49) which are sleeved outside the second open grooves (12) and connected with the filter screen (4).

5. The big data based mechanical equipment fault monitoring device as claimed in claim 3, wherein: the rotation auxiliary part comprises an installation rod (28), a connecting shaft (29), a gear III (30), a belt pulley II (31) and a rotator, the installation rod (28) is symmetrically installed on the top end of the box body (1), one side of the installation rod (28) is rotatably connected with the connecting shaft (29), one end of the connecting shaft (29) is provided with the gear III (30) which is meshed with the gear I (19), the connecting shaft (29) is provided with the belt pulley II (31), and the two belt pulley II (31) are connected through the rotator.

6. The big data based mechanical equipment fault monitoring device as claimed in claim 5, wherein: the rotating device comprises a through groove, a second motor (32), a rotating shaft (33), a third belt pulley (34) and a second belt (35), wherein the top end of the box body (1) is symmetrically provided with the through groove communicated with the first groove (11), the second motor (32) is installed on one side of the first groove (11), an output shaft of the second motor (32) is provided with the rotating shaft (33) connected with the inner wall of the first groove (11), the third belt pulley (34) is symmetrically arranged on the rotating shaft (33), and the third belt pulley (34) and the second belt pulley (31) are connected through the second belt (35) penetrating through the inside of the through groove.

7. The big data based mechanical equipment fault monitoring device as claimed in claim 1, wherein: the air blowing group comprises a first conical gear (36), a fixed seat (37), a rotating seat (38), a second conical gear (39), air blowing fan blades (40) and a fourth belt pulley (41), wherein the first conical gear (36) is symmetrically installed on the rotating shaft (33), the fixed seat (37) is arranged on the rotating shaft (33), the bottom end of the fixed seat (37) is rotatably connected with the rotating seat (38), the fourth belt pulley (41) is symmetrically arranged on the rotating shaft (33), the second conical gear (39) connected with the first conical gear (36) in a meshed mode is arranged on the rotating seat (38), and the air blowing fan blades (40) are arranged at the bottom end of the rotating seat (38).

8. The big data based mechanical equipment fault monitoring device as claimed in claim 1, wherein: suction group is including connecting seat (42), pivot (43), suction fan leaf (44), five (45) of belt pulley, three (46) of belt and scraping piece, and the inner wall top in fluting two (12) is installed in connecting seat (42), and it is connected with pivot (43) to rotate on connecting seat (42), and the one end of pivot (43) is equipped with suction fan leaf (44), is equipped with five (45) of belt pulley on pivot (43), is connected through five (45) of belt pulley between five (45) of belt pulley and four (41) of belt pulley.

9. The big-data-based mechanical equipment fault monitoring device according to claim 8, wherein: the scraping piece comprises a sleeve joint seat (47) and a brush plate (48), the other end of the rotating shaft (43) is provided with the sleeve joint seat (47), and the sleeve joint seat (47) is provided with the brush plate (48) located on one side of the filter screen (4).

10. A method for big data based mechanical device fault monitoring device according to any of claims 1-9, characterized by: the method comprises the following steps:

s1: moving the device to a position to be detected, starting a first motor (22) to rotate forwards, driving a first rotating shaft (20) to rotate by the first motor (22), and driving a sixth gear to rotate by the first rotating shaft (20);

s2: the other rotating shaft I (20) is rotated through the meshing connection of the two gears II, and the rotating shaft II (21) is rotated through the connection relation between the belt pulley I (23) and the belt I (24), so that the gear II (25) is driven to rotate;

s3: the gear teeth (17) drive the height adjusting rod (15) to move upwards through the meshing relation of the gear teeth (17) and the gear teeth (25), the height adjusting rod (15) drives the mounting plate (5) to move upwards through the rotating cylinder (6), the gear teeth (19) are meshed with the gear teeth (30), and the camera body (7) is moved to the outside of the placing box body (1);

s4: the first motor (22) stops rotating, and the second motor (32) rotates;

s5: the second motor (32) drives the third belt pulley (34) to rotate through the rotating shaft (33), the second belt pulley (31) rotates through the connection relation of the second belt (35), the second belt pulley (31) drives the third gear (30) to rotate through the connecting shaft (29), and then the third gear (30) drives the rotating cylinder (6) to rotate through the first gear (19);

s6: the rotating cylinder (6) drives the camera body (7) to rotate through the mounting plate (5), so that the camera body (7) rotates one hundred eighty degrees and is positioned above the mounting plate (5), and then the motor II (32) is turned off, so that the monitoring process of the camera body (7) on the equipment is realized;

s7: after the camera body (7) is monitored, dust is distributed on the surface of the camera body (7), and then a second motor (32) is started to rotate;

s8: the second motor (32) drives the rotating shaft (33) and the third belt pulley (34) to rotate, the second belt pulley (31) rotates through the connection relation of the second belt (35), and the third gear (30) is driven to rotate by the connecting shaft (29);

s9: through the meshing relation of the third gear (30) and the first gear (19), the rotating cylinder (6) drives the mounting plate (5) to rotate by one hundred eighty degrees, the mounting plate (5) drives the camera body (7) to rotate to the position below the mounting plate (5), and the second motor (32) stops acting;

s10: the rotating shaft I (20) is started to rotate reversely, so that the height adjusting rod (15) moves downwards, the height adjusting rod (15) drives the rotating cylinder (6) to move downwards, the rotating cylinder (6) drives the mounting plate (5) to move downwards, the mounting plate (5) drives the camera body (7) to move into the accommodating groove (9), and the mounting plate (5) seals the accommodating groove (9);

s11: starting a second motor (32), wherein the second motor (32) drives a rotating shaft (33) to rotate, the rotating shaft (33) drives a belt pulley fourth (41) and a conical gear first (36) to rotate, the rotating shaft (33) drives a fixed seat (37) to rotate, and the fixed seat (37) drives a conical gear second (39) and a rotating seat (38) to rotate around the rotating shaft (33);

s12: the first conical gear (36) is meshed with the second conical gear (39), so that the second conical gear (39) rotates on the first conical gear (36), and the second conical gear (39) drives the blowing fan blade (40) to rotate;

s13: the air blowing fan blade (40) performs air blowing operation on the accommodating groove (9), can radiate the camera body (7), blows dust on the surface of the camera body (7) and is convenient for dust collection;

s14: the belt III (46) is rotated by rotating the belt pulley IV (41), the belt III (46) can drive the belt pulley V (45) to rotate, the belt pulley V (45) drives the suction fan blade (44) to rotate, dust is sucked, and the dust enters the dust storage box (3) through the slot II (12) to be collected;

s15: the rotating shaft (43) rotates to drive the sleeve joint seat (47) and the brush plate (48) to rotate, the brush plate (48) continuously scrapes the surface of the filter screen (4), dust removal of the filter screen (4) is achieved, and the filter screen (4) is prevented from being blocked to influence the ventilation performance of the box body (1).

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