CN114872840A - Floating type offshore wind measuring platform - Google Patents

Abstract

The invention discloses a floating offshore wind measuring platform which comprises an upper cabin body and a lower cabin body connected below the upper cabin body, wherein the upper cabin body and the lower cabin body are both of a hollow structure, the top surface of the lower cabin body and the bottom of the upper cabin body are both provided with electric wire pipeline holes, a carrying platform is connected in the upper cabin body and used for placing test equipment, an electric power control system and a carrying object are connected in the lower cabin body, the electric power control system is also connected with an electric wire pipeline extending into the upper cabin body through the electric wire pipeline holes, the outer surface of the upper cabin body is connected with a solar power generation board, and the bottom of the lower cabin body is also connected with an anchor chain. The load-bearing platform can be ensured to be basically vertical when mainly stressed by vertical force by releasing energy generated during shaking through the load-bearing platform, and stable measurement conditions are provided for the test equipment arranged on the load-bearing platform.

Description

Floating type offshore wind measuring platform

Technical Field

The invention belongs to the field of wind speed measurement, and particularly relates to a floating offshore wind measuring platform.

Background

Wind energy is an important renewable clean energy source, and ocean wind energy resources are very rich, so that the wind energy generator has a wide development prospect. Offshore wind measurement is an important way to evaluate ocean wind resources to be developed and is also a necessary prerequisite for developing wind power plants.

However, the complex marine environment including ocean currents, waves, strong wind, etc. may generate large shaking, thereby reducing the wind measuring conditions of the wind measuring instrument, and making the collected wind data discontinuous and of reduced quality, which is more obvious for the lidar wind measuring instrument.

Therefore, it is necessary to construct a floating offshore wind measuring platform with strong stability, so that the floating offshore wind measuring platform can weaken or eliminate shaking influences caused by waves, ocean currents and the like, and wind measuring conditions of the lidar wind measuring instrument are fully guaranteed.

Disclosure of Invention

The invention aims to provide a floating offshore wind measuring platform to weaken or eliminate shaking influence caused by waves, ocean currents and the like.

The invention aims to realize a floating offshore wind measuring platform by the following technical means, which comprises an upper cabin body and a lower cabin body connected below the upper cabin body, wherein the upper cabin body and the lower cabin body are both of a hollow structure, the top surface of the lower cabin body and the bottom of the upper cabin body are both provided with electric wire pipeline holes, a carrying platform is connected in the upper cabin body and used for placing test equipment, a power control system and a carrying object are connected in the lower cabin body, the power control system is also connected with an electric wire pipeline extending into the upper cabin body through the electric wire pipeline holes, the outer surface of the upper cabin body is connected with a solar power generation plate, and the bottom of the lower cabin body is also connected with an anchor chain.

The top of the upper cabin body is provided with a detection port, the carrying platform comprises two longitudinal movable hinges, two elastic telescopic rods, a rotating frame, two transverse movable hinges and a bearing platform, the two longitudinal movable hinges are respectively connected to two opposite sides of the detection port, the lower end of each longitudinal movable hinge is connected with one elastic telescopic rod, the lower ends of the two elastic telescopic rods are respectively connected with two opposite sides of the rotating frame, the other two sides of the rotating frame are respectively connected with the transverse movable hinges, and the transverse movable hinges are respectively connected with two opposite sides of the bearing platform through connecting rods.

The bottom of the bearing platform is also provided with a draining port.

The two opposite sides of the detection opening are also connected with suspension connecting rods extending inwards, and the two longitudinal movable hinges are respectively connected to the suspension connecting rods.

The lower cabin body comprises an annular steel mesh and surface steel plates at the top and the bottom of the annular steel mesh, the outer walls of the annular steel mesh and the surface steel plates at the bottom are connected with a porous medium material, the inner walls of the annular steel mesh and the surface steel plates at the bottom are connected with a light foam material, and the power control system and the load are connected on the light foam material on the inner wall of the surface steel plate at the bottom.

The surface steel plate at the top is connected with a connecting frame matched with the bottom of the upper cabin body,

the connection frame outer wall still is connected with many anchor rods, and the anchor rod other end is connected to the annular steel mesh.

The surface steel plate in the connecting frame is provided with a connecting hole matched with the connecting frame, the side walls of the surface steel plates on two opposite sides of the connecting hole are respectively connected with a vertical rotating hinge, and the other side of the vertical rotating hinge is connected with a movable steel plate.

The wire pipeline hole is formed between the two movable steel plates.

The power control system comprises a storage battery and a power regulation and control center, wherein the storage battery is electrically connected with the power regulation and control center, and the power regulation and control center is also electrically connected with the solar power generation panel and the test equipment.

The invention has the beneficial effects that:

1. the longitudinal movable hinge can rotate along the longitudinal direction and is used for releasing energy generated during front and back shaking, the elastic telescopic rod can realize that the rotating frame overturns up and down and is used for releasing partial energy generated during left and right shaking, the transverse movable hinge can rotate along the transverse direction and is used for releasing energy generated during left and right shaking, and by the structure, the bearing platform can be guaranteed to be mainly kept vertical under the action of force in the vertical direction, so that stable measuring conditions are provided for testing equipment arranged on the bearing platform.

2. The porous medium material outside the annular steel mesh can effectively eliminate the influence of waves.

3. The lower cabin body can be opened and closed through the vertical rotating hinge and the movable steel plate, and the internal objects are easy to take out and convenient to disassemble, assemble and transport.

Drawings

FIG. 1 is a schematic elevation view of a floating offshore wind measuring platform;

FIG. 2 is a three-dimensional schematic view of a carrier platform;

FIG. 3 is a schematic plan view of the upper deck;

FIG. 4 is a schematic view of the upper deck in elevation;

FIG. 5 is a schematic plan view of the lower deck;

FIG. 6 is a schematic view of the lower deck in elevation;

FIG. 1, test equipment; 2. an upper cabin body; 3. a solar power panel; 4. sea level; 5. a lower cabin body; 6. carrying a heavy object; 7. a power control system; 8. and (4) an anchor chain. 2-1, a longitudinal movable hinge; 2-2, an elastic telescopic rod; 2-3, rotating the frame; 2-4, a transverse movable hinge; 2-5, carrying a platform; 2-6, draining port; 2-7, a prismatic table type steel frame; 5-1, porous medium material; 5-2, an annular steel mesh; 5-3, surface steel plate; 5-4, square frame; 5-5, vertically rotating the hinge; 5-6, movable steel plates; 5-7, reinforcing rods; 5-8, wire pipelines; 5-9, a lightweight foam material; 7-1, electric power regulation center; 7-2 and a storage battery.

The present invention will be described in further detail with reference to the accompanying drawings and examples.

Detailed Description

[ example 1 ]

The utility model provides a float formula offshore wind measuring platform, includes the upper cabin body 2 and connects the lower cabin body 5 in the upper cabin body 2 below, the upper cabin body 2 is hollow structure with lower cabin body 5, and electric wire pipeline hole has all been opened to lower cabin body 5 top surface and upper cabin body 2 bottom, and 2 in-connection in the upper cabin body have cargo platform, and cargo platform is used for placing test equipment 1, and 5 in-connections in the lower cabin body have electric power control system 7 and carry heavy object 6, still is connected with the electric wire pipeline 5-8 that stretches into the upper cabin body 2 through electric wire pipeline hole on the electric power control system 7, 2 outer surface connections in the upper cabin body have solar panel 3, and 5 bottoms in the lower cabin body still are connected with anchor chain 8.

As shown in fig. 1, the device comprises an upper cabin 2 for placing the testing equipment 1, and a lower cabin 5 for supporting the upper cabin 2 and providing buoyancy, wherein the upper cabin 2 and the lower cabin 5 are both hollow structures for placing the testing equipment, the power control system 7 and other components inside.

Wherein, the upper cabin body 2 is internally connected with a carrying platform for placing a test device 1, such as a laser radar wind meter. The outer wall of the upper cabin body 2 is connected with a solar power generation board 3.

The main body of the upper cabin body 2 is composed of frustum pyramid type steel frames 2-7 which gradually shrink from bottom to top, the solar power generation panel 3 is connected to the outer side walls of the frustum pyramid type steel frames 2-7, and the frustum pyramid type steel frames 2-7 which gradually shrink from bottom to top are more stable in structure.

Place electric power control system 7 and year heavy object 6 in the lower cabin body 5, electric power control system 7 is connected with test equipment 1 and solar panel 3 electricity respectively, controls opening of test equipment 1 and stops and the power supply, stores the electric quantity that solar panel 3 produced. And the heavy object 6, such as a sand bag and other heavy objects, is used for increasing the balance weight, reducing the gravity center of the whole equipment and enhancing the whole stability. As shown in fig. 1, the lower hull 5 is mostly below sea level 4.

Likewise, the anchor chains 8 at the bottom of the lower hull 5 are used to anchor the entire platform.

[ example 2 ]

On the basis of the embodiment 1, the top of the upper cabin body 2 is provided with a detection port, the carrying platform comprises two longitudinal movable hinges 2-1, two elastic telescopic rods 2-2, a rotating frame 2-3, two transverse movable hinges 2-4 and a bearing platform 2-5, the two longitudinal movable hinges 2-1 are respectively connected to two opposite sides of the detection port, the lower end of the longitudinal movable hinge 2-1 is connected with one elastic telescopic rod 2-2, the lower ends of the two elastic telescopic rods 2-2 are respectively connected to two opposite sides of the rotating frame 2-3, the other two sides of the rotating frame 2-3 are respectively connected with the transverse movable hinges 2-4, and the transverse movable hinges 2-4 are respectively connected to two opposite sides of the bearing platform 2-5 through connecting rods.

And the bottom of the bearing platform 2-5 is also provided with a draining port 2-6.

Two opposite sides of the detection port are also connected with suspension connecting rods extending inwards, and two longitudinal movable hinges 2-1 are respectively connected with the suspension connecting rods.

As shown in fig. 2 to 4, the top of the upper cabin 2 is provided with a detection port for the equipment on the loading platform to detect the external environment information. The carrier platform is attached to the side wall of the probe port.

As shown in fig. 2, the loading platform firstly comprises two longitudinal movable hinges 2-4, the two longitudinal movable hinges 2-4 are respectively connected at two opposite sides of the detecting opening, as shown in figure 2, connected to the left and right sides, a vertically downward elastic expansion link 2-2 is connected below each longitudinal movable hinge 2-4, the lower ends of the two elastic expansion links 2-2 are respectively connected to the two opposite sides of the rotating frame 2-3, as shown in fig. 2, is connected to the left and right sides of the rotating frame 2-3, the transverse movable hinge 2-4 is connected to the other two sides of the rotating frame 2-3, as shown in figure 2, the test device 1 is connected to the front side and the rear side of a rotating frame 2-3, a transverse movable hinge 2-4 is connected with a bearing platform 2-5 through a downward rigid connecting rod, and the test device is placed on the bearing platform 2-5.

The longitudinal movable hinge 2-1 can rotate along the longitudinal direction and is used for releasing energy generated during front and back shaking, the elastic telescopic rod 2-2 can realize that the rotating frame 2-3 can be turned over up and down and is used for releasing partial energy generated during left and right shaking, and the transverse movable hinge 2-4 can rotate along the transverse direction and is used for releasing energy generated during left and right shaking.

When the platform integrally shakes back and forth, due to the existence of the longitudinal movable hinge 2-1, force in the front and back direction cannot be transmitted to the elastic telescopic rod 2-2, the elastic telescopic rod 2-2 can be basically vertical under the action of the pulling force of a heavy object below, firstly, the longitudinal movable hinge 2-1 can freely rotate back and forth, so that the resistance applied to the rotation of the elastic telescopic rod is small, and force cannot be easily transmitted to the elastic telescopic rod when other objects rotate according to the acting force and the reacting force, namely, the force is not applied. Like ice with small friction, people are not easy to walk.

Therefore, when the platform integrally shakes forwards and backwards, according to the relative movement, the longitudinal movable hinge 2-1 is not labored and does not rotate, but the frustum pyramid type steel frame 2-7 connected with the longitudinal movable hinge 2-1 rotates, because the longitudinal movable hinge 2-1 does not rotate forwards and backwards, a rod below the longitudinal movable hinge is straight, and the lower part of the whole device is equivalent to be free of forward and backward displacement, so that the platform is stable.

When the platform integrally shakes leftwards and rightwards, although the frustum pyramid type steel frame 2-7 can incline, the elastic telescopic rod 2-2 is stretched or contracted, the rotating frame 2-3 rotates, the transverse movable hinge 2-4 is basically not influenced, force in the left and right direction cannot be transmitted to the bearing platform 2-5, the bearing platform 2-5 can basically keep vertical under the action of gravity, when the platform shakes leftwards and rightwards, the rotating frame 2-4 can swing with the longitudinal movable hinge 2-1 as a center instead of rotating on the assumption that the elastic rod 2-3 is rigid, the lower part is easy to generate large displacement, but because the elastic rod 2-3 is an elastic rod, when the platform shakes leftwards and rightwards, the elastic rod 2-3 can contract, force generated when the platform shakes leftwards and rightwards can act on the rotating frame 2-4 to rotate more, when the rotating frame 2-4 rotates, the force is not easy to be transferred to the transverse movable hinge 2-2, because the transverse movable hinge 2-2 can freely rotate along the left and right directions, and the rotating frame 2-4 can freely rotate at the contact position of the transverse hinge 2-2 according to the interaction of the force action.

Therefore, through the three displacement releasing processes of the longitudinal movable hinge 2-1, the rotating frame 2-4 and the transverse movable hinge 2-2, when the lower bearing platform 2-5 is heavier, the bearing platform 2-5 is not easy to displace in the front-back or left-right directions, and mainly displaces in the upper and lower directions. The stability is further improved, and therefore the test equipment 1 in the test equipment has a better wind measuring condition.

The draining port 2-6 discharges rainwater and the like falling from the detecting port from the bearing platform 2-5.

[ example 3 ]

In addition to the embodiment 2, further, as shown in fig. 3, inwardly extending suspension bars are connected to the side walls on opposite sides of the detection port, and two longitudinal living hinges 2-1 are respectively connected to the two suspension bars. The two supporting connecting rods which are perpendicular to the hanging connecting rods can be arranged, the two ends of each supporting connecting rod are connected to the other two sides of the detection port, the middle points of the supporting connecting rods are connected with the ends, extending out of the hanging connecting rods, of the supporting connecting rods, the supporting connecting rods and the hanging connecting rods form a stable structure, and the weight of the whole loading platform can be better borne.

[ example 4 ]

On the basis of the embodiment 1, as shown in fig. 1, 5 and 6, the lower cabin body 5 comprises an annular steel net 5-2 and surface steel plates 5-3 at the top and the bottom of the annular steel net 5-2, the outer walls of the annular steel net 5-2 and the surface steel plates 5-3 at the bottom are connected with a porous medium material 5-1, the inner walls of the annular steel net 5-2 and the surface steel plates 5-3 at the bottom are connected with a light foam material 5-9, and a power control system 7 and a load weight 6 are connected with the light foam material 5-9 at the inner walls of the surface steel plates 5-3 at the bottom.

The lower chamber body 5 comprises an annular steel net 5-2 forming the side wall, a surface steel plate 5-3 closing the upper top surface and the lower bottom surface of the annular steel net 5-2, the annular steel net 5-2 and the upper and lower surface steel plates 5-3 form a closed cylindrical chamber body,

the annular steel net 5-2 is used for bearing the internal and external forces of the whole lower cabin body 5, and the surface steel plate 5-3 seals the annular steel net 5-2 to prevent water from entering.

The outer porous media material 5-1, such as filter sponge and plastic wave-dissipating tow board, acts as a wave-dissipating, and the inner lightweight foam material 5-9, such as syntactic foam, synthetic rubber and lightweight wood board, acts as an internal water barrier and reduces the impact of the internal power control system 7 and the load 6.

As shown in figure 5, a connecting frame 5-4 matched with the bottom of the upper cabin body 2 is connected to the surface steel plate 5-3 at the top.

The outer wall of the connecting frame 5-4 is also connected with a plurality of reinforcing rods 5-7, and the other ends of the reinforcing rods 5-7 are connected to the annular steel net 5-2.

The surface steel plate 5-3 at the top is connected with a connecting frame 5-2 for placing and fixing the upper cabin body 2, and the surface steel plate 5-3 below the connecting frame 5-2 is provided with an electric wire channel hole for a power supply line channel 5-8 to pass through.

A plurality of reinforcing rods 5-7 may be further attached to the outer wall of the coupling frame 5-4, and the reinforcing rods 5-7 are attached to the inner wall of the steel ring net 5-2 to further fix the coupling frame 5-4.

The surface steel plate 5-3 in the connecting frame 5-4 is provided with a connecting hole matched with the connecting frame 5-4, the side walls of the surface steel plate 5-3 at the two opposite sides of the connecting hole are respectively connected with a vertical rotating hinge 5-5, and the other side of the vertical rotating hinge 5-5 is connected with a movable steel plate 5-6.

The wire duct hole is arranged between the two movable steel plates 5-6.

Furthermore, in order to facilitate taking out the articles in the lower cabin body 5, a connecting hole matched with the connecting frame 5-4 is arranged on the surface steel plate 5-3 below the connecting frame 5-4, vertical rotating hinges 5-5 are connected on the two opposite sides of the surface steel plate 5-3 of the connecting hole, a movable steel plate 5-6 is connected on the other side of the vertical rotating hinge 5-5, so that a movable door capable of being opened and closed is formed, an electric wire pipeline hole for passing a power supply pipeline 5-8 is arranged between the two movable steel plates 5-6, as shown in figure 5, a semicircular hole is arranged on each movable steel plate 5-6, the two movable steel plates are combined to form a round hole, a sealing ring is connected on the electric wire pipeline hole, water is prevented from leaking into the lower cabin body 5 from a gap between the electric wire pipeline and the electric wire pipeline hole, and the hinge 5-5 is vertically rotated, The contact part of the movable steel plates 5-6 and the connecting hole is also connected with a sealing ring to prevent water seepage.

The power control system 7 comprises a storage battery 7-2 and a power regulation and control center 7-1, the storage battery 7-2 and the power regulation and control center 7-1 are electrically connected with each other, and the power regulation and control center 7-1 is also electrically connected with the solar power generation panel 3 and the test equipment 1.

The power control system comprises a storage battery 7-2 and a power regulation and control center 7-1 which are electrically connected with each other, are also connected with the solar power generation panel 3 and the testing equipment 1, supply power to the testing equipment 1, and charge the storage battery 7-2 through the solar power generation panel 3.

Further, a load 6 such as a sandbag may be placed on the storage battery 7-2 and the electric power control center 7-1 to stabilize the storage battery 7-2 and the electric power control center 7-1. And arranging a plurality of columns and rows of raised parts on the light foam material 5-9 in the inner part, thereby dividing the bottom into a grid shape, then placing the storage battery 7-2 and the power regulation and control center 7-1 in the grid, and further fixing the positions of the storage battery 7-2 and the power regulation and control center 7-1 to prevent mutual collision.

The electric wire of the electric power regulation and control center 7-1 penetrates through the electric wire pipeline 5-8, enters the upper cabin body 2 through the electric wire pipeline 5-8, is electrically connected with the testing equipment 1 of the upper cabin body 2 and the solar power generation board 3, and the electric wire pipeline hole at the bottom of the upper cabin body 2 is also connected with a sealing ring to prevent water from permeating into the lower cabin body 5. And the electric wire pipelines 5-8 extend out of a part of the bottom of the upper cabin body 2, so as long as the accumulated water in the upper cabin body 2 is not higher than the upper ends of the electric wire pipelines 5-8, no accumulated water enters the lower cabin body 5, and the upper ends of the electric wire pipelines 5-8 are not in contact with the bearing platform 2-5, so that the bearing platform 2-5 is prevented from being influenced.

Claims (10)

1. A floating offshore wind measuring platform, comprising: go up cabin body (2) and connect lower cabin body (5) of last cabin body (2) below, go up cabin body (2) and lower cabin body (5) and be hollow structure, electric wire conduit hole has all been opened to lower cabin body (5) top surface and last cabin body (2) bottom, go up cabin body (2) in-connection and have cargo platform, cargo platform is used for placing test equipment (1), cabin body (5) in-connection has electric power control system (7) and carried heavy object (6) down, still is connected with electric wire conduit (5-8) that stretch into the upper cabin body (2) through electric wire conduit hole on electric power control system (7), it is connected with solar panel (3) to go up cabin body (2) surface, and lower cabin body (5) bottom still is connected with anchor chain (8).

2. A floating offshore wind measuring platform according to claim 1, wherein: the top of the upper cabin body (2) is provided with a detection port, the carrying platform comprises two longitudinal movable hinges (2-1) and two elastic telescopic rods (2-2), the detection device comprises a rotating frame (2-3), two transverse movable hinges (2-4) and a bearing platform (2-5), wherein the two longitudinal movable hinges (2-1) are respectively connected to two opposite sides of a detection port, the lower end of each longitudinal movable hinge (2-1) is connected with an elastic telescopic rod (2-2), the lower ends of the two elastic telescopic rods (2-2) are respectively connected with two opposite sides of the rotating frame (2-3), the other two sides of the rotating frame (2-3) are respectively connected with the transverse movable hinges (2-4), and the transverse movable hinges (2-4) are respectively connected with two opposite sides of the bearing platform (2-5) through connecting rods.

3. A floating offshore wind measuring platform according to claim 2, wherein: and a draining port (2-6) is also arranged at the bottom of the bearing platform (2-5).

4. A floating offshore wind measuring platform according to claim 2, wherein: two opposite sides of the detection port are also connected with suspension connecting rods extending inwards, and two longitudinal movable hinges (2-1) are respectively connected with the suspension connecting rods.

5. A floating offshore wind measuring platform according to claim 1, wherein: the lower cabin body (5) comprises an annular steel mesh (5-2) and surface steel plates (5-3) at the top and the bottom of the annular steel mesh (5-2), the outer walls of the annular steel mesh (5-2) and the surface steel plates (5-3) at the bottom are connected with porous medium materials (5-1), the inner walls of the annular steel mesh (5-2) and the surface steel plates (5-3) at the bottom are connected with light foam materials (5-9), and a power control system (7) and a load (6) are connected to the light foam materials (5-9) on the inner walls of the surface steel plates (5-3) at the bottom.

6. A floating offshore wind measuring platform according to claim 5, wherein: the surface steel plate (5-3) at the top is connected with a connecting frame (5-4) matched with the bottom of the upper cabin body (2).

7. A floating offshore wind measuring platform according to claim 6, wherein: the outer wall of the connecting frame (5-4) is also connected with a plurality of reinforcing rods (5-7), and the other ends of the reinforcing rods (5-7) are connected to the annular steel net (5-2).

8. A floating offshore wind measuring platform according to claim 6, wherein: the surface steel plate (5-3) in the connecting frame (5-4) is provided with a connecting hole matched with the connecting frame (5-4), the side walls of the surface steel plate (5-3) at two opposite sides of the connecting hole are respectively connected with a vertical rotating hinge (5-5), and the other side of the vertical rotating hinge (5-5) is connected with a movable steel plate (5-6).

9. A floating offshore wind measuring platform according to claim 8, wherein: the wire pipeline hole is arranged between the two movable steel plates (5-6).

10. A floating offshore wind measuring platform according to claim 1, wherein: the power control system (7) comprises a storage battery (7-2) and a power regulation and control center (7-1), the storage battery (7-2) and the power regulation and control center (7-1) are electrically connected with each other, and the power regulation and control center (7-1) is also electrically connected with the solar power generation panel (3) and the test equipment (1).

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