CN217084608U - Corrosion monitoring equipment for offshore wind power steel structure - Google Patents

Abstract

The utility model discloses a corrosion monitoring device for an offshore wind power steel structure, which comprises a fixed plate and a cleaning assembly; fixing a plate: mounting holes are symmetrically formed in four corners of the fixing plate, a connecting column is arranged on the left side face of the fixing plate, a guide rail is arranged on the left side face of the connecting column, a transverse plate is connected to the middle of the guide rail in a sliding mode, a T-shaped sliding groove is formed in the front side face of the guide rail, the right end of the transverse plate is connected with the inner wall of the T-shaped sliding groove in a sliding mode, an air bag is arranged in the middle of the outer surface of the transverse plate, a support is arranged on the upper surface of the front end head of the transverse plate, a camera is fixedly connected to the upper surface of a vertical plate body of the support, the output end of the camera is electrically connected with the output end of a single chip microcomputer arranged on the upper surface of the connecting column, and the input end of the single chip microcomputer is electrically connected with an external power supply; cleaning the component: set up in the vertical plate body middle part of support, the mirror surface cooperation setting of clearance subassembly and camera, this marine wind power steel construction corrosion monitoring equipment ensures that the camera monitors the surface of water region of marine wind power steel construction all the time, has guaranteed the monitoring effect.

Description

Corrosion monitoring equipment for offshore wind power steel structure

Technical Field

The utility model relates to a monitoring facilities technical field specifically is a marine wind power steel construction corrosion monitoring equipment.

Background

An offshore wind power plant is a novel power plant for generating power by utilizing offshore wind resources, is sustainable new energy, is beneficial to reducing the use of fossil energy and improving the environment, generally adopts a single-column or rack-type fixing mode and the like according to different depths of an existing offshore wind power generation foundation, ensures stability, and saves cost to the maximum extent, but is buried in seawater to have higher corrosion efficiency than that in dry air, and the flowing seawater causes possible generated wrapping salt to lose and accelerates corrosion, so that tracking inspection is needed to ensure the safety of a wind power generator, and in a severe offshore environment, a steel structure is positioned at the position of the seawater surface and is most easily corroded due to simultaneous seawater impact, atmospheric corrosion and sunlight irradiation, the service life of the offshore wind power generator set structure foundation is easily damaged, and even serious safety accidents are caused, current marine wind power steel construction corrosion monitoring equipment is direct fixed mounting usually, but marine environment is complicated, and the sea level can be along with weather condition's change and constantly go up and down, and the camera can not follow the lift of sea level and go up and down, and detection effect is poor, and the camera is after long-time work moreover, and the remaining sea salt of sea water evaporation on lens surface leads to the fact easily to shelter from, leads to detection effect not good, for this reason, we provide a marine wind power steel construction corrosion monitoring equipment.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide a marine wind power steel construction corrosion monitoring equipment, ensure that the camera monitors the surface of water region of marine wind power steel construction all the time, can strike off the sea salt on camera surface, guaranteed the monitoring effect, can effectively solve the problem in the background art.

In order to achieve the above object, the utility model provides a following technical scheme: a corrosion monitoring device for an offshore wind power steel structure comprises a fixing plate and a cleaning assembly;

fixing a plate: mounting holes are symmetrically formed in four corners of the fixing plate, a connecting column is arranged on the left side face of the fixing plate, a guide rail is arranged on the left side face of the connecting column, a transverse plate is connected to the middle of the guide rail in a sliding mode, a support is arranged on the upper surface of a head at the front side of the transverse plate, a camera is fixedly connected to the upper surface of a vertical plate body of the support, the output end of the camera is electrically connected with the output end of a single chip microcomputer arranged on the upper surface of the connecting column, and the input end of the single chip microcomputer is electrically connected with an external power supply;

cleaning the component: set up in the vertical plate body middle part of support, the mirror surface cooperation setting of clearance subassembly and camera ensures that the camera is monitored the surface of water region of offshore wind power steel construction all the time, can strike off the sea salt on camera surface, has guaranteed the monitoring effect.

Furthermore, the front side of the guide rail is provided with a T-shaped sliding groove, and the right end of the transverse plate is in sliding connection with the inner wall of the T-shaped sliding groove to keep the transverse plate horizontal.

Furthermore, the middle part of the outer surface of the transverse plate is provided with an air bag, and the height of the camera is adjusted to be always positioned above the sea surface.

Further, the clearance subassembly includes motor, pivot and scraper blade, the motor sets up in the vertical plate body left surface middle part of support, and the output shaft of motor is connected with the vertical plate body internal rotation of support, and the output shaft right-hand member of motor is equipped with the pivot, and the right-hand member of pivot is equipped with the scraper blade, and the left surface of scraper blade sets up with the mirror surface cooperation of camera, and singlechip output is connected to the input electricity of motor, clears up the mirror surface of camera, avoids the sea salt influence monitoring effect of camera mirror surface crystallization.

Further, the lower extreme of scraper blade is equipped with spherical groove, and the inside symmetry of scraper blade is equipped with the runner, and the lower extreme of runner all communicates with spherical groove is inside, and the upper end of runner all extends to the left surface of scraper blade, and spherical groove is located the lower surface below of gasbag, to the mirror surface pouring sea water of camera, improves clean effect.

Further, still include wireless signal transmitter, wireless signal transmitter sets up in the upper surface of spliced pole, and wireless signal transmitter is connected with the two-way electricity of singlechip, conveys the monitoring picture through radio signal, reduces the cable and lays the cost, conveniently overhauls the maintenance simultaneously.

Further, still include protective housing, protective housing sets up in the upper surface of spliced pole, and wireless signal transmitter and singlechip all are located protective housing's inside, protect wireless signal transmitter and singlechip, avoid receiving the wave for a long time and assault and break down.

Compared with the prior art, the beneficial effects of the utility model are that: this marine wind power steel construction corrosion monitoring equipment has following benefit:

the fixing plate is fixedly connected with the offshore wind power steel structure, the camera monitors the water surface area of the offshore wind power steel structure in real time, the air bag floats on the surface of seawater, the camera can lift along with the lifting of the sea level, after the camera works for a long time, seawater evaporation remained on the mirror surface of the camera can separate out sea salt, the monitoring effect is influenced, a signal is sent to the wireless signal transmitter through an external terminal at the moment, the motor is started through the single chip microcomputer, the output shaft of the motor drives the rotating shaft to rotate, the rotating shaft drives the scraper to rotate, the lower end of the scraper is positioned below the air bag, the seawater is scooped up through the spherical groove after the lower end of the scraper is submerged into the water surface, the seawater in the spherical groove flows to the left side of the scraper through the flow channel along with the continuous rotation of the scraper, the left side of the scraper is attached to the mirror surface of the camera at the moment, so that the mirror surface of the camera is wetted, and the separated salt can be thoroughly erased, this marine wind power steel construction corrosion monitoring equipment ensures that the camera is monitored the surface of water region of marine wind power steel construction all the time, can strike off the sea salt on camera surface, has guaranteed the monitoring effect.

Drawings

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

fig. 2 is a schematic sectional view of the scraper of the present invention.

In the figure: the device comprises a fixing plate 1, a connecting column 2, a guide rail 3, a 31T-shaped sliding groove, a transverse plate 4, a support 5, a camera 6, an air bag 7, a cleaning assembly 8, a motor 81, a rotating shaft 82, a scraping plate 83, a spherical groove 831, a runner 832, a protective shell 9, a wireless signal transmitter 10 and a singlechip 11.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present embodiment provides a technical solution: the corrosion monitoring equipment for the offshore wind power steel structure comprises a fixing plate 1 and a cleaning assembly 8;

fixing a plate 1: mounting holes are symmetrically formed in four corners of the marine wind power steel structure, a connecting column 2 is arranged on the left side face of a fixing plate 1, a guide rail 3 is arranged on the left side face of the connecting column 2, a transverse plate 4 is slidably connected to the middle of the guide rail 3, a T-shaped chute 31 is arranged on the front side face of the guide rail 3, the right end of the transverse plate 4 is slidably connected with the inner wall of the T-shaped chute 31, the transverse plate 4 is kept horizontal, an air bag 7 is arranged in the middle of the outer surface of the transverse plate 4, the height of a camera 6 is adjusted to be always located above the sea level, a support 5 is arranged on the upper surface of the front side end head of the transverse plate 4, a camera 6 is fixedly connected to the upper surface of a vertical plate body of the support 5, the output end of the camera 6 is electrically connected with the output end of a single chip microcomputer 11 arranged on the upper surface of the connecting column 2, the input end of the single chip microcomputer 11 is electrically connected with an external power supply, the air bag 7 always floats on the sea level, the camera 6 can lift along with the lift of the sea level, and the camera 6 can always monitor the water surface area of the marine wind power steel structure;

cleaning component 8: the cleaning component 8 is arranged in the middle of a vertical plate body of the support 5 in a matched manner with the mirror surface of the camera 6, the cleaning component 8 comprises a motor 81, a rotating shaft 82 and a scraper 83, the motor 81 is arranged in the middle of the left side surface of the vertical plate body of the support 5, an output shaft of the motor 81 is rotatably connected with the inside of the vertical plate body of the support 5, the right end of the output shaft of the motor 81 is provided with the rotating shaft 82, the right end of the rotating shaft 82 is provided with the scraper 83, the left side surface of the scraper 83 is arranged in a matched manner with the mirror surface of the camera 6, an input end of the motor 81 is electrically connected with an output end of the singlechip 11 to clean the mirror surface of the camera 6, the monitoring effect influenced by salt crystallized on the mirror surface of the camera 6 is avoided, the lower end of the scraper 83 is provided with a spherical groove 831, the inside of the scraper 83 is symmetrically provided with a flow channel 832, the lower end of the flow channel 832 is communicated with the inside of the spherical groove 831, the upper end of the flow channel 832 extends to the left side surface of the scraper 83, the spherical groove 831 is positioned below the lower surface of the airbag 7, the motor 81 is started through the singlechip 11, the output shaft of the motor 81 drives the rotating shaft 82 to rotate, the rotating shaft 82 drives the scraper 83 to rotate, the lower end of the scraper 83 is located below the air bag 7, the lower end of the scraper 83 is submerged into the water surface and scoops up seawater through the spherical groove 831, the seawater in the spherical groove 831 flows to the left side surface of the scraper 83 through the flow channel 832 along with the continuous rotation of the scraper 83, the left side surface of the scraper 83 is attached to the mirror surface of the camera 6 at the moment, and therefore the mirror surface of the camera 6 is wetted, and precipitated salt can be thoroughly erased conveniently.

Wherein: still include wireless signal transmitter 10, wireless signal transmitter 10 sets up in the upper surface of spliced pole 2, and wireless signal transmitter 10 is connected with 11 two-way electricity of singlechip, conveys the monitoring picture through radio signal, reduces the cable and lays the cost, and convenient the maintenance of overhauing simultaneously.

Wherein: still include protecting sheathing 9, protecting sheathing 9 sets up in the upper surface of spliced pole 2, and wireless signal transmitter 10 and singlechip 11 all are located protecting sheathing 9's inside, protect wireless signal transmitter 10 and singlechip 11, avoid receiving the wave for a long time and assault and break down.

The utility model provides a pair of marine wind power steel construction corrosion monitoring equipment's theory of operation as follows:

the fixing plate 1 is fixedly connected with the offshore wind power steel structure, the camera 6 carries out real-time monitoring on the water surface area of the offshore wind power steel structure, and transmits monitoring signals to an external terminal through the wireless signal transmitter 10, because the airbag 7 floats on the surface of seawater, the camera 6 can lift along with the lifting of the sea level, the camera 6 is ensured to always monitor the water surface area of the offshore wind power steel structure, after the camera 6 works for a long time, seawater remained on the mirror surface of the camera evaporates to separate out sea salt, which affects the monitoring effect, at the moment, the external terminal sends signals to the wireless signal transmitter 10, the motor 81 is started through the singlechip 11, the output shaft of the motor 81 drives the rotating shaft 82 to rotate, the rotating shaft 82 drives the scraper 83 to rotate, the lower end of the scraper 83 is positioned below the airbag 7, the seawater is scooped up through the spherical groove 831 after the lower end of the scraper 83 sinks into the water surface, and rotates along with the continuous rotation of the scraper 83, seawater in the spherical groove 831 flows to the left side surface of the scraper 83 through the flow channel 832, and at the moment, the left side surface of the scraper 83 is attached to the mirror surface of the camera 6, so that the mirror surface of the camera 6 is wetted, and the precipitated salt can be thoroughly erased.

It should be noted that the camera 6, the motor 81 and the wireless signal transmitter 10 disclosed in the above embodiments can be freely configured according to practical application scenarios, the camera 6 is suggested to use a zoom web camera, the motor 81 can use a 750W vertical gear reduction motor, the wireless signal transmitter 10 can use ST5801GB-M series ad hoc network wireless transmission system, and the single chip 11 controls the camera 6, the motor 81 and the wireless signal transmitter 10 to work by a method commonly used in the prior art.

The above is only the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention can be used in other related technical fields, directly or indirectly, or in the same way as the present invention.

Claims (7)

1. The utility model provides an offshore wind power steel construction corrosion monitoring equipment which characterized in that: comprises a fixed plate (1) and a cleaning component (8);

fixing plate (1): mounting holes are symmetrically formed in four corners of the fixing plate, a connecting column (2) is arranged on the left side face of the fixing plate (1), a guide rail (3) is arranged on the left side face of the connecting column (2), a transverse plate (4) is connected to the middle of the guide rail (3) in a sliding mode, a support (5) is arranged on the upper surface of the front side end of the transverse plate (4), a camera (6) is fixedly connected to the upper surface of the vertical plate body of the support (5), the output end of the camera (6) is electrically connected with the output end of a single chip microcomputer (11) arranged on the upper surface of the connecting column (2), and the input end of the single chip microcomputer (11) is electrically connected with an external power supply;

cleaning assembly (8): set up in the vertical plate body middle part of support (5), the mirror surface cooperation setting of clearance subassembly (8) and camera (6).

2. The offshore wind power steel structure corrosion monitoring device according to claim 1, characterized in that: the front side of the guide rail (3) is provided with a T-shaped sliding groove (31), and the right end of the transverse plate (4) is in sliding connection with the inner wall of the T-shaped sliding groove (31).

3. The offshore wind power steel structure corrosion monitoring device according to claim 1, characterized in that: and an air bag (7) is arranged in the middle of the outer surface of the transverse plate (4).

4. The offshore wind power steel structure corrosion monitoring device according to claim 1, characterized in that: clearance subassembly (8) are including motor (81), pivot (82) and scraper blade (83), motor (81) set up in the vertical plate body left surface middle part of support (5), and the output shaft of motor (81) is connected with the inside rotation of the vertical plate body of support (5), and the output shaft right-hand member of motor (81) is equipped with pivot (82), and the right-hand member of pivot (82) is equipped with scraper blade (83), and the left surface of scraper blade (83) sets up with the mirror surface cooperation of camera (6), and singlechip (11) output is connected to the input electricity of motor (81).

5. The offshore wind power steel structure corrosion monitoring device according to claim 4, characterized in that: the lower extreme of scraper blade (83) is equipped with spherical groove (831), and the inside symmetry of scraper blade (83) is equipped with runner (832), and the lower extreme of runner (832) all communicates with spherical groove (831) is inside, and the upper end of runner (832) all extends to the left surface of scraper blade (83).

6. The offshore wind power steel structure corrosion monitoring device according to claim 1, characterized in that: still include wireless signal transmitter (10), wireless signal transmitter (10) set up in the upper surface of spliced pole (2), and wireless signal transmitter (10) and singlechip (11) two-way electricity are connected.

7. The offshore wind power steel structure corrosion monitoring device according to claim 6, characterized in that: still include protecting sheathing (9), protecting sheathing (9) set up in the upper surface of spliced pole (2), and wireless signal transmitter (10) and singlechip (11) all are located the inside of protecting sheathing (9).

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