CN116951262A - Hydropower station cloud monitoring device and method based on BIM - Google Patents

Abstract

The invention relates to the technical field of cloud monitoring devices and provides a hydropower station cloud monitoring device and a hydropower station cloud monitoring method based on BIM, the hydropower station cloud monitoring device comprises a support upright post, a base and a cloud monitoring device body, wherein the base is assembled on the support upright post in a sliding mode, the top of the support upright post is fixedly connected with a limiting plate through a screw, a driving motor is started to drive the base to ascend through arrangement of a synchronous belt I, a synchronous belt II and the like, meanwhile, rotation of a driving shaft is achieved through arrangement of a large gear and the synchronous belt I, further movement of a driving rack plate is achieved, movement of a driven rack plate is achieved through a connecting rod, rotation of a driving gear is achieved, rotation of a transmission helical gear II and a transmission helical gear I is achieved, rotation of a door shaft is achieved through arrangement of the synchronous belt II, and accordingly closing of a door is achieved. Through above-mentioned technical scheme, the security of having solved among the prior art is poor, inconvenient maintenance problem.

Description

Hydropower station cloud monitoring device and method based on BIM

Technical Field

The invention relates to the technical field of cloud monitoring devices, in particular to a hydropower station cloud monitoring device and method based on BIM.

Background

BIM technology is a datamation tool applied to engineering design, construction and management, and is shared and transferred in the whole life cycle process of project planning, operation and maintenance through the integration of datamation and informatization models of buildings. BIM has five characteristics of visualization, coordination, simulation, optimality and diagrammability.

The authorized bulletin number in the prior art is: cloud monitoring equipment of a photovoltaic power station of CN 219198759U; the application provides cloud supervisory equipment of photovoltaic power plant belongs to supervisory equipment technical field, and this cloud supervisory equipment of photovoltaic power plant includes lifting unit and cloud supervisory equipment, lifting unit includes bottom plate, stand, sliding seat, motor, gear wheel and rack board, stand fixed connection in the bottom plate top, the sliding seat slide cup joint in the stand surface, cloud supervisory equipment includes cloud surveillance camera head, rolling plate and solar panel, cloud surveillance camera head install in the sliding seat top, through setting up bottom plate, stand, sliding seat, motor, gear wheel and rack board, not only can conveniently adjust the high being applicable to different situations of cloud surveillance camera head, rolling plate and solar panel, the maintenance of dismantling of cloud surveillance camera head is carried out to convenient non-maintainer simultaneously, carries out real-time cloud surveillance through setting up cloud surveillance camera head, rolling plate and solar panel, however this invention realizes the lift of cloud surveillance device body through the drive of gear wheel and motor to realize the control and change and maintenance of cloud surveillance camera head, but the motor bump the condition down, and other can take place the illumination accident very much more can not take place with the equipment of illumination safety and safety to the electrical equipment under the circumstances of the night.

Disclosure of Invention

The invention provides a hydropower station cloud monitoring device and method based on BIM, which solve the problems of poor safety and inconvenient maintenance in the related technology.

The technical scheme of the invention is as follows:

the utility model provides a hydropower station cloud monitoring device based on BIM, includes support post, base and cloud monitoring device body, the base sliding fit is in on the support post, the top of support post is through screw fixedly connected with limiting plate, the bottom of support post is through screw connection has a supporting baseplate, one side fixedly connected with drive rack board of support post, the internally mounted of base has driving motor, driving motor's output fixedly connected with drive shaft, the welding has drive gear on the outer peripheral face of drive shaft, drive gear with drive rack board meshes mutually, the bottom of base is fixedly connected with cloud monitoring device control box and guard plate respectively, two door shafts are installed in the rotation on the cloud monitoring device control box, two all fixedly connected with chamber doors on the outer peripheral face of door shaft, the protection casing is installed at the top of base, the bottom of base with be provided with inspection device jointly on the cloud monitoring device control box, the bottom of cloud monitoring device control box is provided with switching device, the top of base is provided with monitoring device, the inside of monitoring device body is provided with temperature sensor and warning light respectively;

the inspection device comprises a fixed seat, two symmetrically arranged fixed plates are fixedly connected to one side of a control box of the cloud monitoring device, a transmission shaft is installed on the fixed plates in a rotating mode, the fixed seat is fixedly connected to the bottom of the base through screws, a driving rack plate and a driven rack plate are respectively and slidably assembled on the fixed seat, connecting rods are fixedly connected to one sides of the driving rack plate and the driven rack plate through screws, supporting blocks are fixedly connected to two sides of the fixed seat through screws, a driven shaft and a driving shaft are respectively installed on the supporting blocks in a rotating mode, two rack blocks are assembled in the driving rack plate in a sliding mode, and a rotating shaft is installed in the base in a rotating mode.

As a preferable scheme of the invention, the switch device comprises a switch shaft, a lamp panel is arranged on the inner wall of a control box of the cloud monitoring device, an elastic switch is arranged on the lamp panel, a sliding rod is slidably arranged on the control box of the cloud monitoring device, the bottom end of the sliding rod is fixedly connected with a driving plate through a screw, two symmetrically arranged fixing blocks are fixedly connected with the bottom of the control box of the cloud monitoring device through the screw, the switch shaft is rotatably arranged on the two fixing blocks, and one end of the switch shaft is fixedly connected with an eccentric wheel through the screw.

As a preferable scheme of the invention, the monitoring device comprises a rotating seat, wherein the rotating seat is rotatably arranged at the top of the base, two symmetrically arranged supporting vertical plates are fixedly connected to the top of the rotating seat through screws, a rotating rod is rotatably arranged on one side of each supporting vertical plate, and the cloud monitoring device body is fixedly connected to the outer peripheral surface of the rotating rod.

As a preferable scheme of the invention, the outer peripheral surfaces of the transmission shaft and one of the door shafts are fixedly sleeved with a synchronous wheel II, synchronous belts II are jointly mounted on the outer peripheral surfaces of the two synchronous wheels II, synchronous wheels I are fixedly sleeved on the outer peripheral surfaces of the driving shaft and the rotating shaft, and synchronous belts I are jointly mounted on the outer peripheral surfaces of the two synchronous wheels I.

As a preferable scheme of the invention, a large gear and a small gear are respectively fixedly sleeved on the peripheral surfaces of the rotating shaft and the driving shaft, the large gear is meshed with the small gear, a driving gear and a driven gear are respectively fixedly sleeved on the peripheral surfaces of the driving shaft and the driven shaft, and the driving gear and the driven gear are respectively meshed with the driving rack plate and the driven rack plate.

As a preferable scheme of the invention, round holes are formed in the two supporting blocks, the driving shaft and the driven shaft are respectively and rotatably arranged in the two round holes, a transmission helical gear II and a transmission helical gear I are respectively and fixedly sleeved on the peripheral surfaces of the driven shaft and the transmission shaft, and the transmission helical gear I is meshed with the transmission helical gear II.

As a preferable scheme of the invention, two symmetrically arranged sliding grooves are formed in the driving rack plate, an orientation rod is fixedly connected to the inner wall of the sliding groove through a screw, the tooth block is slidably connected to the inner part of the sliding groove, an orientation hole is formed in the tooth block, the orientation rod penetrates through the inside of the orientation hole, a driving spring is welded on one side of the tooth block, the other end of the driving spring is welded on the inner wall of the sliding groove, a groove is formed in the inner part of the fixing seat, and the driving rack plate and the driven rack plate are slidably connected to the inner part of the groove.

As a preferable scheme of the invention, a through groove is formed in the control box of the cloud monitoring device, the sliding rod is connected in the through groove in a sliding manner, a reset spring is welded at the top of the driving plate, and the other end of the reset spring is welded at the bottom of the control box of the cloud monitoring device.

As a preferable scheme of the invention, one end of the switch shaft and one end of one of the door shafts are respectively fixedly connected with a driving bevel gear and a driven bevel gear through screws, and the driving bevel gear is meshed with the driven bevel gear.

The hydropower station cloud monitoring device based on BIM comprises the following specific steps:

s1: the method comprises the steps that a worker installs the cloud monitoring device body and devices inside a cloud monitoring device control box;

s2: after the installation, the remote control driving motor is started, so that the driving shaft drives the driving gear to rotate, and then the base is driven to move, so that the cloud monitoring device body moves downwards, and further the hydropower station is better monitored;

s3: when maintenance is needed, the remote control driving motor drives the driving shaft to rotate reversely, so that the base moves downwards, and the door is opened while the base moves downwards through the driving shaft, the driven shaft and the door shaft in the moving process;

s4: after the maintenance personnel finishes the inspection, maintenance and maintenance of the cloud monitoring device body and the internal devices of the cloud monitoring device control box, the remote control driving motor is started again, so that the base moves downwards, and the monitoring work is continued.

The working principle and the beneficial effects of the invention are as follows:

1. according to the invention, through the arrangement of the structures of the first synchronous belt and the second synchronous belt, the driving motor starts to drive the base to ascend, and simultaneously, the driving shaft is rotated through the arrangement of the large gear and the first synchronous belt, so that the movement of the driving rack plate is realized, the movement of the driven rack plate is realized through the connecting rod, the rotation of the driving gear is realized, the rotation of the transmission helical gear II and the transmission helical gear I is realized, the rotation of the door shaft is realized through the arrangement of the second synchronous belt, the closing of the door is realized, and further, the protection of devices in the control box of the cloud monitoring device is realized, otherwise, when the base descends, the door is opened, and the maintenance of the devices in the control box of the cloud monitoring device is more convenient for staff.

2. According to the invention, through the arrangement of the eccentric wheel, the sliding rod and other structures, the door shaft drives the driving bevel gear to rotate, the driving bevel gear drives the driven bevel gear to rotate, the driven bevel gear drives the switch shaft to rotate, and the switch shaft drives the eccentric wheel to rotate so as to drive the movement of the plate and the sliding rod, so that the sliding rod presses the elastic switch to switch the lamp panel, and when the door is opened, the lamp panel is opened to illuminate for maintenance personnel, and further the maintenance personnel can maintain the internal components of the control box of the cloud monitoring device more safely.

3. According to the invention, through the arrangement of the structures such as the rotating seat, the rotating rod and the like, the rotating seat drives the supporting vertical plate, the rotating rod and the cloud monitoring device body to rotate, so that the cloud monitoring device body is enabled to perform more omnibearing monitoring, and the rotating rod drives the cloud monitoring device body to perform angle adjustment, so that the cloud monitoring device body is enabled to perform multi-angle monitoring, further, the cloud monitoring device body is enabled to perform more comprehensive monitoring, and the practicability of the device is enabled to be better.

Drawings

The invention will be described in further detail with reference to the drawings and the detailed description.

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

FIG. 2 is a schematic view of the whole structure of the base of the present invention;

FIG. 3 is a schematic view of the overall structure of the inspection apparatus of the present invention;

FIG. 4 is a front view of the present invention;

FIG. 5 is a front view of the base of the present invention;

FIG. 6 is a front view of the inspection apparatus of the present invention;

FIG. 7 is a side view of the holder of the present invention;

FIG. 8 is a side view of the large and small gears of the present invention;

FIG. 9 is an enlarged view of the invention at reference A;

fig. 10 is a side view of the monitoring device of the present invention.

In the figure: 1. A support column; 2. a base; 3. a support base plate; 4. driving the rack plate; 8. a driving motor; 9. a drive shaft; 10. a drive gear; 11. a cloud monitoring device control box; 12. a door spindle; 13. cloud monitoring device body; 14. a door; 15. a protection plate; 16. a protective cover; 17. a limiting plate;

5. an inspection device; 50. a fixing plate; 51. a transmission shaft; 52. a first transmission bevel gear; 53. a fixing seat; 54. a support block; 55. a driven shaft; 56. a driven gear; 57. a transmission helical gear II; 58. driven rack plate; 59. a connecting rod; 500. a driving shaft; 501. a drive gear; 502. a drive rack plate; 503. tooth blocks; 504. a directional rod; 505. a drive spring; 506. a synchronous belt I; 507. a rotating shaft; 508. a large gear; 509. a pinion gear; 510. a synchronous belt II;

6. a switching device; 60. a driving helical gear; 61. a fixed block; 62. a switching shaft; 63. driven helical gears; 64. a lamp panel; 65. an elastic switch; 66. an eccentric wheel; 67. a slide bar; 68. a driving plate; 69. a return spring;

7. a monitoring device; 70. a rotating seat; 71. a supporting vertical plate; 72. and rotating the rod.

Detailed Description

The technical solutions of the embodiments of the present invention will be clearly and completely described below in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

As shown in fig. 1-10, the embodiment provides a hydropower station cloud monitoring device based on BIM, which comprises a supporting upright 1, a base 2 and a cloud monitoring device body 13, wherein the base 2 is slidingly assembled on the supporting upright 1, the top of the supporting upright 1 is fixedly connected with a limiting plate 17 through screws, the bottom of the supporting upright 1 is connected with a supporting bottom plate 3 through screws, one side of the supporting upright 1 is fixedly connected with a driving rack plate 4, a driving motor 8 is internally installed in the base 2, the output end of the driving motor 8 is fixedly connected with a driving shaft 9, a driving gear 10 is welded on the peripheral surface of the driving shaft 9, the driving gear 10 is meshed with the driving rack plate 4, the bottom of the base 2 is fixedly connected with a cloud monitoring device control box 11 and a protection plate 15 respectively, two door shafts 12 are rotatably installed on the cloud monitoring device control box 11, box doors 14 are fixedly connected on the peripheral surfaces of the two door shafts 12 respectively, a protection cover 16 is installed on the top of the base 2, an inspection device 5 is jointly arranged on the bottom of the base 2 and the cloud monitoring device control box 11, a switch device 6 is arranged at the bottom of the cloud monitoring device control box 11, a temperature sensor 13 is arranged in the base 2, and a temperature sensor is arranged in the cloud monitoring device 13; the inspection device 5 comprises a fixed seat 53, two symmetrically arranged fixed plates 50 are fixedly connected to one side of a control box 11 of the cloud monitoring device, a transmission shaft 51 is mounted on the two fixed plates 50 in a rotating mode, the fixed seat 53 is fixedly connected to the bottom of a base 2 through screws, a driving rack plate 502 and a driven rack plate 58 are respectively and slidably mounted on the fixed seat 53, a connecting rod 59 is fixedly connected to one side of the driving rack plate 502 and one side of the driven rack plate 58 through screws, supporting blocks 54 are fixedly connected to two sides of the fixed seat 53 through screws, a driven shaft 55 and a driving shaft 500 are respectively and rotatably mounted on the two supporting blocks 54, two rack blocks 503 are slidably mounted inside the driving rack plate 502, a rotating shaft 507 is rotatably mounted inside the base 2, through the setting of hold-in range one 506, hold-in range two 510 isotructures, when driving motor 8 starts to drive base 2 and rises, realize the rotation of driving shaft 500 through the setting of gear wheel 508 and hold-in range one 506, and then realize the motion of initiative rack board 502, realize the motion of driven rack board 58 through connecting rod 59, realize the rotation of driving gear 501, thereby realize the rotation of transmission helical gear two 57 and transmission helical gear one 52, realize the rotation of door axle 12 through the setting of hold-in range two 510, thereby realize the closing of chamber door 14, and then protect the inside device of cloud monitoring device control box 11, otherwise, when base 2 descends, chamber door 14 is opened, more make things convenient for the staff to maintain the inside device of cloud monitoring device control box 11.

As shown in fig. 5 to 6, the outer peripheral surfaces of the transmission shaft 51 and one of the door shafts 12 are fixedly sleeved with a second synchronizing wheel, the outer peripheral surfaces of the two second synchronizing wheels are jointly provided with a second synchronizing belt 510, the outer peripheral surfaces of the driving shaft 500 and the rotating shaft 507 are fixedly sleeved with a first synchronizing wheel, and the outer peripheral surfaces of the two first synchronizing wheels are jointly provided with a first synchronizing belt 506.

As shown in fig. 5 to 9, a large gear 508 and a small gear 509 are fixedly sleeved on the outer peripheral surfaces of the rotating shaft 507 and the driving shaft 9, the large gear 508 and the small gear 509 are meshed, a driving gear 501 and a driven gear 56 are fixedly sleeved on the outer peripheral surfaces of the driving shaft 500 and the driven shaft 55, and the driving gear 501 and the driven gear 56 are meshed with the driving rack plate 502 and the driven rack plate 58.

As shown in fig. 6, the two supporting blocks 54 are provided with round holes, the driving shaft 500 and the driven shaft 55 are respectively and rotatably installed in the two round holes, the outer peripheral surfaces of the driven shaft 55 and the driving shaft 51 are respectively and fixedly sleeved with a transmission helical gear II 57 and a transmission helical gear I52, and the transmission helical gear I52 and the transmission helical gear II 57 are meshed.

As shown in fig. 5-9, two symmetrically arranged sliding grooves are formed in the driving rack plate 502, a directional rod 504 is fixedly connected to the inner wall of each sliding groove through a screw, a tooth block 503 is slidably connected to the inner portion of each sliding groove, a directional hole is formed in each tooth block 503, the directional rod 504 penetrates through the inner portion of each directional hole, a driving spring 505 is welded to one side of each tooth block 503, the other end of each driving spring 505 is welded to the inner wall of each sliding groove, a groove is formed in the inner portion of each fixing seat 53, and the driving rack plate 502 and the driven rack plate 58 are slidably connected to the inner portion of each groove.

In this embodiment, the driving motor 8 drives the driving shaft 9 to rotate, the driving shaft 9 drives the driving gear 10 to rotate, the driving gear 10 and the driving rack plate 4 are meshed to drive the base 2 to move upwards while the driving gear 10 rotates, the driving shaft 9 drives the pinion 509 to rotate, the pinion 509 drives the large gear 508 to rotate, the large gear 508 drives the rotating shaft 507 to rotate, the driving shaft 500 is driven to rotate by the synchronous belt 506, the driving shaft 500 drives the driving gear 501 to rotate, the driving gear 501 drives the driving rack plate 502 to move, the driven rack plate 58 is driven by the connecting rod 59 to further drive the driven gear 56 and the driven shaft 55 to rotate, the driven shaft 55 drives the driving helical gear two 57 to rotate, the driving helical gear two 57 drives the driving helical gear one 52 to rotate, and the driving helical gear two 57 and the driving shaft 51 are further rotated, the door shaft 12 is rotated through the synchronous belt II 510, so that the door 14 is closed, otherwise, the driving shaft 9 is reversed, when the base 2 moves downwards, the door 14 is opened in the same way as the operation, the driving rack plate 502, the driven rack plate 58 and other parts cannot limit the rotation of the driving gear 10 through the arrangement of the tooth block 503 and the driving spring 505, after the driving rack plate rises to the top, the cloud monitoring device body 13 is driven to monitor the hydropower station, the abnormal condition of the hydropower station during the internal work is sensed through equipment such as a temperature sensor, the alarm lamp is driven to flash, the abnormal condition of the staff is warned, the inspection device 5, the switch device 6 and the cloud monitoring device body 13 are maintained through the protection plate 15 and the protection cover 16, and the limiting plate 17 limits the base 2, so that the support upright 1 is prevented from moving out.

Example 2

As shown in fig. 1 to 10, based on the same concept as that of the above embodiment 1, this embodiment further proposes that the switching device 6 includes a switching shaft 62, a lamp plate 64 is installed on the inner wall of the control box 11 of the cloud monitoring device, an elastic switch 65 is installed on the lamp plate 64, a sliding rod 67 is slidably assembled on the control box 11 of the cloud monitoring device, the bottom end of the sliding rod 67 is fixedly connected with a driving plate 68 through a screw, the bottom of the control box 11 of the cloud monitoring device is fixedly connected with two symmetrically arranged fixing blocks 61 through a screw, the switching shaft 62 is rotatably installed on the two fixing blocks 61, one end of the switching shaft 62 is fixedly connected with an eccentric wheel 66 through a screw, through the arrangement of the eccentric wheel 66, the sliding rod 67 and other structures, the door shaft 12 drives a driving bevel gear 60 to rotate, the driving bevel gear 60 drives a driven bevel gear 63 to rotate, the driven bevel gear 63 drives the switching shaft 62 to rotate, the eccentric wheel 66 drives the eccentric wheel 66 to rotate so as to drive the movement of the driving plate 68 and the sliding rod 67, and further the sliding rod 67 presses the elastic switch 65 to switch the lamp plate 64, when the door 14 is opened, the lamp plate 64 is further, and a maintainer is further to perform lighting for maintenance.

As shown in fig. 6, a through groove is formed in the control box 11 of the cloud monitoring device, a sliding rod 67 is slidably connected in the through groove, a return spring 69 is welded at the top of the driving plate 68, and the other end of the return spring 69 is welded at the bottom of the control box 11 of the cloud monitoring device.

As shown in fig. 6, one end of the switch shaft 62 and one end of one of the door shafts 12 are fixedly connected with a driving bevel gear 60 and a driven bevel gear 63 by screws, respectively, and the driving bevel gear 60 and the driven bevel gear 63 are engaged.

In this embodiment, when the internal devices of the cloud monitoring device body 13 and the cloud monitoring device control box 11 need to be maintained, the door shaft 12 drives the box door 14 to open and simultaneously drives the driving bevel gear 60 to rotate, the driving bevel gear 60 drives the driven bevel gear 63 to rotate, the driven bevel gear 63 drives the switch shaft 62 to rotate, the switch shaft 62 drives the eccentric wheel 66 to rotate, and then the eccentric position of the eccentric wheel 66 pushes the driving plate 68 to realize the movement of the sliding rod 67, the sliding rod 67 extrudes the elastic switch 65 to open the lamp panel 64, so that the illumination is realized, the working personnel can perform more convenient maintenance work safely, and when the back-up box door 14 is closed, the reset spring 69 drives the driving plate 68 and the sliding rod 67 to reset, the elastic switch 65 resets, the lamp panel 64 is closed, and electric resources are saved.

Example 3

As shown in fig. 2-10, based on the same concept as that of the foregoing embodiments 1 and 2, this embodiment further proposes that the monitoring device 7 includes a rotating seat 70, the rotating seat 70 is rotatably mounted on the top of the base 2, two symmetrically arranged supporting risers 71 are fixedly connected to the top of the rotating seat 70 through screws, a rotating rod 72 is rotatably mounted on one side of the two supporting risers 71, the cloud monitoring device body 13 is fixedly connected to the outer peripheral surface of the rotating rod 72, the rotating seat 70 drives the supporting risers 71, the rotating rod 72 and the cloud monitoring device body 13 to rotate through the arrangement of the rotating seat 70, the rotating rod 72 and the like, so that the cloud monitoring device body 13 performs more omnibearing monitoring, and the rotating rod 72 drives the cloud monitoring device body 13 to perform angle adjustment, so that the cloud monitoring device body 13 performs multi-angle monitoring, and further the cloud monitoring device body 13 performs more comprehensive monitoring, so that the practicability of the device is better.

In this embodiment, the rotating seat 70 drives the supporting vertical plate 71, the rotating rod 72 and the cloud monitoring device body 13 to rotate, so that the cloud monitoring device body 13 is monitored more omnidirectionally, and the rotating rod 72 drives the cloud monitoring device body 13 to adjust the angle, so that the cloud monitoring device body 13 is monitored at multiple angles, and further the cloud monitoring device body 13 is monitored more comprehensively.

The hydropower station cloud monitoring device based on BIM comprises the following specific steps:

s1: the staff installs the internal devices of the cloud monitoring device body 13 and the cloud monitoring device control box 11;

s2: after the installation, the remote control driving motor 8 is started, so that the driving shaft 9 drives the driving gear 10 to rotate, and then the base 2 is driven to move, so that the cloud monitoring device body 13 moves downwards, and further the hydropower station is better monitored;

s3: when maintenance is needed, the remote control driving motor 8 drives the driving shaft 9 to rotate reversely, so that the base 2 moves downwards, and the door 14 is opened while the base 2 moves downwards in the moving process through the driving shaft 500, the driven shaft 55 and the door shaft 12;

s4: after the maintenance personnel finishes the inspection, maintenance and maintenance of the internal devices of the cloud monitoring device body 13 and the cloud monitoring device control box 11, the remote control driving motor 8 is started again, so that the base 2 moves downwards to continue the monitoring work.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (10)

1. The utility model provides a hydropower station cloud monitoring device based on BIM, its characterized in that includes support post (1), base (2) and cloud monitoring device body (13), base (2) sliding fit is in on support post (1), the top of support post (1) is through screw fixedly connected with limiting plate (17), there is bottom plate (3) in the bottom of support post (1) through screw connection, one side fixedly connected with drive tooth board (4) of support post (1), internally mounted of base (2) has driving motor (8), the output fixedly connected with drive shaft (9) of driving motor (8), welding on the outer peripheral face of drive shaft (9) has driving gear (10), driving gear (10) with drive tooth board (4) mesh mutually, the bottom of base (2) is fixedly connected with cloud monitoring device control box (11) and guard plate (15) respectively, install two door axles (12) on cloud monitoring device control box (11) rotation, two on door axle (12) outer peripheral face (14) are connected with driving shaft (9), cloud monitoring device (2) are installed on the outer peripheral face (2) of base (2) and are equipped with top inspection device (5), the bottom of the cloud monitoring device control box (11) is provided with a switch device (6), the top of the base (2) is provided with a monitoring device (7), and a temperature sensor and a warning lamp are respectively arranged in the cloud monitoring device body (13);

the inspection device (5) comprises a fixed seat (53), two symmetrically arranged fixed plates (50) are fixedly connected to one side of a control box (11) of the cloud monitoring device, a transmission shaft (51) is installed on the fixed plates (50) in a rotating mode, the fixed seat (53) is fixedly connected to the bottom of the base (2) through screws, a driving rack plate (502) and a driven rack plate (58) are respectively and slidably assembled on the fixed seat (53), a connecting rod (59) is fixedly connected to one side of the driving rack plate (502) and one side of the driven rack plate (58) through screws, supporting blocks (54) are fixedly connected to two sides of the fixed seat (53) through screws, a driven shaft (55) and a driving shaft (500) are respectively installed on the supporting blocks (54) in a rotating mode, two rack blocks (503) are installed in a sliding mode, and a rotating shaft (507) is installed in the inner portion of the base (2).

2. The hydropower station cloud monitoring device based on BIM according to claim 1, wherein the switching device (6) comprises a switching shaft (62), a lamp panel (64) is installed on the inner wall of a cloud monitoring device control box (11), an elastic switch (65) is installed on the lamp panel (64), a sliding rod (67) is slidably installed on the cloud monitoring device control box (11), the bottom end of the sliding rod (67) is fixedly connected with a driving plate (68) through a screw, the bottom of the cloud monitoring device control box (11) is fixedly connected with two symmetrically arranged fixed blocks (61) through the screw, the switching shaft (62) is rotatably installed on the two fixed blocks (61), and one end of the switching shaft (62) is fixedly connected with an eccentric wheel (66) through the screw.

3. The hydropower station cloud monitoring device based on BIM according to claim 2, wherein the monitoring device (7) comprises a rotating seat (70), the rotating seat (70) is rotatably installed at the top of the base (2), two symmetrically arranged supporting vertical plates (71) are fixedly connected to the top of the rotating seat (70) through screws, a rotating rod (72) is rotatably installed on one side of each supporting vertical plate (71), and the cloud monitoring device body (13) is fixedly connected to the outer peripheral surface of the rotating rod (72).

4. A hydropower station cloud monitoring device based on BIM according to claim 3, wherein the transmission shaft (51) and the outer peripheral surface of one of the door shafts (12) are fixedly sleeved with a second synchronizing wheel, the outer peripheral surfaces of the two second synchronizing wheels are jointly provided with a second synchronizing belt (510), the outer peripheral surfaces of the driving shaft (500) and the rotating shaft (507) are fixedly sleeved with a first synchronizing wheel, and the outer peripheral surfaces of the two first synchronizing wheels are jointly provided with a first synchronizing belt (506).

5. The hydropower station cloud monitoring device based on BIM according to claim 4, wherein a large gear (508) and a small gear (509) are fixedly sleeved on the outer peripheral surfaces of the rotating shaft (507) and the driving shaft (9), the large gear (508) and the small gear (509) are meshed, a driving gear (501) and a driven gear (56) are fixedly sleeved on the outer peripheral surfaces of the driving shaft (500) and the driven shaft (55), and the driving gear (501) and the driven gear (56) are meshed with the driving rack plate (502) and the driven rack plate (58).

6. The BIM-based hydropower station cloud monitoring device according to claim 5, wherein round holes are formed in two supporting blocks (54), the driving shaft (500) and the driven shaft (55) are respectively rotatably installed in the two round holes, a transmission bevel gear II (57) and a transmission bevel gear I (52) are respectively fixedly sleeved on the outer peripheral surfaces of the driven shaft (55) and the transmission shaft (51), and the transmission bevel gear I (52) and the transmission bevel gear II (57) are meshed.

7. The hydropower station cloud monitoring device based on BIM according to claim 6, wherein two symmetrically arranged sliding grooves are formed in the driving rack plate (502), a directional rod (504) is fixedly connected to the inner wall of each sliding groove through a screw, the tooth block (503) is slidably connected to the inner portion of each sliding groove, a directional hole is formed in the tooth block (503), the directional rod (504) penetrates through the inner portion of each directional hole, a driving spring (505) is welded on one side of the tooth block (503), the other end of each driving spring (505) is welded on the inner wall of each sliding groove, a groove is formed in the inner portion of each fixing seat (53), and the driving rack plate (502) and the driven rack plate (58) are slidably connected to the inner portion of each groove.

8. The hydropower station cloud monitoring device based on BIM according to claim 7, wherein a through groove is formed in a control box (11) of the cloud monitoring device, the sliding rod (67) is slidably connected in the through groove, a return spring (69) is welded at the top of the driving plate (68), and the other end of the return spring (69) is welded at the bottom of the control box (11) of the cloud monitoring device.

9. The hydropower station cloud monitoring device based on BIM according to claim 8, wherein one end of the switch shaft (62) and one end of the door shaft (12) are fixedly connected with a driving bevel gear (60) and a driven bevel gear (63) through screws respectively, and the driving bevel gear (60) is meshed with the driven bevel gear (63).

10. The hydropower station cloud monitoring method based on BIM adopts the hydropower station cloud monitoring device based on BIM as claimed in claim 9, and is characterized by comprising the following specific steps:

s1: the staff installs the internal devices of the cloud monitoring device body (13) and the cloud monitoring device control box (11);

s2: after the installation, the remote control driving motor (8) is started, so that the driving shaft (9) drives the driving gear (10) to rotate, and then the base (2) is driven to move, so that the cloud monitoring device body (13) moves downwards, and further the hydropower station is monitored better;

s3: when maintenance is needed, the remote control driving motor (8) drives the driving shaft (9) to rotate reversely, so that the base (2) moves downwards, and the door (14) is opened while the base (2) moves downwards in the moving process through the driving shaft (500), the driven shaft (55) and the door shaft (12);

s4: after the maintenance personnel finishes the inspection, maintenance and maintenance of the internal devices of the cloud monitoring device body (13) and the cloud monitoring device control box (11), the remote control driving motor (8) is started again, so that the base (2) moves downwards to continue monitoring work.