CN113581375A - Buoy device applied to water conservancy monitoring and application method thereof - Google Patents

Abstract

The invention discloses a buoy device applied to water conservancy monitoring and a using method thereof, and the buoy device comprises a buoy, wherein the buoy is connected with a plurality of floating balls, the floating balls are rotationally connected with lower sliding rods arranged in the inclining direction, the lower sliding rods penetrate through the floating balls, the upper ends of the lower sliding rods are connected with upper sliding rods, and the upper sliding rods are connected with wind vanes in a sliding manner; the lower end of the lower sliding rod is connected with a plurality of sliding seats in a sliding mode, the sliding seats are connected with the wind vane through pull ropes, the sliding seats are hinged to supporting rods through supporting rods, elastic cloth is connected between adjacent supporting rods, the upper ends of the supporting rods are hinged to the outer wall of the lower sliding rod, and the sliding seats are connected with the lower sliding rod through reset springs. The invention can adjust the opening amplitude of the elastic cloth in a self-adaptive way along with the direction and the force of the wind waves, greatly reduces the fluctuation of the buoy, and effectively reduces the detection error caused by the fluctuation of the buoy.

Description

Buoy device applied to water conservancy monitoring and application method thereof

Technical Field

The invention relates to the technical field of water conservancy detection, in particular to a buoy device applied to water conservancy monitoring and a using method thereof.

Background

The buoy on the sea surface is subjected to environmental loads such as wind, wave and current, and a large swing response occurs. The influence of the rocking motion on the buoy is mainly reflected in two aspects: firstly, the observation of parameters such as buoy hydrology and weather is greatly influenced by the swing motion of the buoy, and generally, the smaller the swing angle of the buoy is, the higher the measurement accuracy of the detection sensor is; secondly, the swinging of the buoy affects the registration, maintenance and repair work of the buoy maintenance personnel. Ocean observation buoys carry numerous detection instruments which are in service in high humidity, high salinity ocean environments and are subject to the action of strong winds and waves, have much higher rates of aging and damage than those on land, and require shorter periods of equipment maintenance and repair.

Therefore, the reasonable control of the swing angle of the buoy in the wind waves is an important index for buoy design. Buoys belong to single point moorings and are usually anchored to the sea floor by anchor chains. Due to the fact that sea conditions are complex and difficult to predict, the buoy is in a shaking state at any time due to impact of waves, once sea waves are too large, the buoy tends to overturn, the buoy is easy to damage, the service life of the buoy is shortened, and the monitoring result of the monitoring device is influenced.

Disclosure of Invention

In order to solve the problems in the prior art, the buoy device applied to water conservancy monitoring and the using method thereof are provided.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the invention provides a buoy device applied to water conservancy monitoring, which comprises a buoy, wherein the buoy is connected with a plurality of floating balls, the floating balls are rotationally connected with lower sliding rods arranged in the inclining direction, the lower sliding rods penetrate through the floating balls, the upper ends of the lower sliding rods are connected with upper sliding rods, and the upper sliding rods are connected with wind vane markers in a sliding manner; the lower end of the lower sliding rod is slidably connected with a plurality of sliding seats, the sliding seats are connected with the wind vane through pull ropes, the sliding seats are hinged to supporting rods through supporting rods and are adjacent to the supporting rods, elastic cloth is connected between the supporting rods, the upper end of each supporting rod is hinged to the outer wall of the lower sliding rod, and the sliding seats are connected with the lower sliding rod through reset springs.

Preferably, a plurality of groups of sliding grooves are formed in the two ends of the lower sliding rod, each group of sliding grooves comprises two sliding grooves which are symmetrically arranged on the two sides of the lower sliding rod, the two sliding grooves are internally and evenly connected with the sliding seats in a sliding mode, and the two sliding seats are symmetrically arranged on the two sides of the lower sliding rod.

Preferably, a cavity is formed in the lower sliding rod and the upper sliding rod, the sliding grooves are communicated with the cavity, a connecting plate is connected between the sliding seats, and the connecting plate is connected with the sliding grooves in a sliding mode.

Preferably, a spring fixing plate fixedly connected with the inner wall of the lower sliding rod is arranged in the cavity, the reset spring is arranged in the cavity in a sliding mode, the upper end of the reset spring is connected with the spring fixing plate, and the lower end of the reset spring is connected with the connecting plate.

Preferably, the wind vane is connected with the pull rope in a sliding mode through a pull rope connecting plate, a plurality of supporting wheels are arranged in the cavity in a rotating mode, the pull rope is hung on the supporting wheels, and the connecting plate is connected after the pull rope penetrates through the spring fixing plate.

Preferably, the lower sliding rod is connected with rotating discs, the floating ball is arranged between the rotating discs, and the floating ball is rotatably connected with the rotating discs.

Preferably, the buoys are connected with the floating balls through pull rods, and the number of the floating balls is four; a detecting instrument is arranged in the buoy, and the buoy is further connected with a solar panel.

Preferably, the included angle between the lower sliding rod and the upper sliding rod is an acute angle.

The invention also provides a using method of the buoy device applied to water conservancy monitoring, and the buoy device applied to water conservancy monitoring comprises the following steps:

s1, placing the buoy on the water surface to be monitored, adjusting a plurality of wind direction wind indicators to be in the downwind direction under the action of wind force along with the blowing of wind, and simultaneously driving the sliding rod to rotate around the floating ball by the wind direction wind indicators;

s2: the wind vane is driven to slide along the upper sliding rod along with the blowing of wind, the wind vane drives the sliding seat to slide upwards along the lower sliding rod through the pull rope, the sliding seat drives the supporting rods to be opened through the supporting rods, and therefore the elastic cloth between the supporting rods is driven to be opened, and the thrust of stormy waves is balanced.

Preferably, the windward side of the lower sliding rod and the included angle between the windward side of the lower sliding rod and the wind waves are an obtuse angle, and when the wind force is reduced, the sliding seat slides downwards along the lower sliding rod under the action of the return spring, so that the opening range of the supporting rods is reduced, and the opening degree of the elastic cloth between the supporting rods is further reduced.

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

1. the floating ball type wind vane device is provided with the plurality of floating balls and the wind direction wind vane, the wind direction wind vane is driven to float on the water surface under the action of the floating balls, the wind direction wind vane is adjusted to be in the downwind direction under the action of sea wind, and then the lower sliding rod is driven to rotate, so that the included angle between the windward side of the lower sliding rod and the wind wave is an obtuse angle, better supporting capacity is achieved, the structure is reasonable, the rotating angle of the supporting rod is automatically adjusted according to the change of the following wind direction, and the floating ball type wind vane device is better in wind wave resistance, economical and practical and has high popularization value.

2. The wind vane can slide along the upper sliding rod under the action of wind waves, the sliding seat is driven to slide through the pull rope, the supporting rod is driven to open through the supporting rod, the elastic cloth is opened, the thrust of the waves can be balanced when the wind waves hit, the overturning phenomenon is reduced, the vibration of the buoy is reduced, the opening size of the elastic cloth changes along with the size of the wind force, the opening amplitude is large when the wind force is large, the balance effect of the thrust of the wind waves is facilitated, the buoy is kept stable all the time, the shaking is reduced, the buoy damage phenomenon is effectively prevented, the service life of the buoy is prolonged, and the monitoring quality of the monitoring device is improved.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is an overall front view of the present invention;

FIG. 2 is an enlarged view of the portion A in FIG. 1;

FIG. 3 is an enlarged view of the portion B of FIG. 1;

FIG. 4 is an overall top view of the present invention;

FIG. 5 is a top view of the wind vane portion of FIG. 4;

fig. 6 is an overall front view (in an operating state) of the present invention.

Description of reference numerals:

1 sliding a rod; 2, a pull rod; 3, a buoy; 4 a solar panel; 5, a sliding seat; 6, a support rod; 7 a return spring; 8 supporting rods; 9 pulling a rope; 10, fixing a base; 11 sliding the sliding rod; 12, pulling a rope connecting plate; 13 wind vane; 14 supporting wheels; 15 rotating the disc; 16 a floating ball; 17 a sliding groove; 18 a cavity; 19 a spring fixing plate; 20 connecting the plates.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

As shown in fig. 1-6, the embodiment provides a buoy device for water conservancy monitoring, which includes a buoy 3, the buoy 3 is connected with a plurality of floating balls 16, the floating balls 16 are rotatably connected with lower sliding rods 1 arranged in an inclined direction, the lower sliding rods 1 penetrate through the floating balls 16, and the upper ends of the lower sliding rods 1 are connected with upper sliding rods 11.

The buoy 3 is connected with the floating ball 16 through the pull rod 2, the floating ball 16 floats on the water surface in a normal state, and the buoy 3 floats on the water surface all the time under the action of the pull rod 2.

The floating balls 16 are arranged in four, and the floating balls 16 are respectively arranged in the front, the rear, the left and the right directions of the buoy 3, so that the four-point support effect on the buoy 3 is achieved.

Set up detecting instrument in the buoy 3, detecting instrument is used for normal water level monitoring work, can be provided with different detecting instrument according to actual need, buoy 3 still is connected with solar panel 4, and solar panel 4 is used for detecting instrument's power supply work, does benefit to the long-time work of detecting instrument.

The lower sliding rod 1 is divided into an upper part and a lower part, wherein the upper part penetrates through the floating ball 16 and is arranged in the direction vertical to the water surface, the lower part is arranged in the inclined direction, an included angle between the lower part of the lower sliding rod 1 and the upper sliding rod 11 is an acute angle, the arrangement is equivalent to the arrangement in the vertical direction, the lower sliding rod 1 arranged in the inclined mode has a larger contact surface with the stormy waves, and the contact surface is always in the direction along the stormy waves, so that the better capability of resisting the stormy waves is possessed when the stormy waves are favorably hit.

The upper sliding rod 11 is fixedly connected with the lower sliding rod 1, the upper sliding rod 11 is connected with the wind vane 13 in a sliding mode, and the wind vane 13 can only slide along the length direction of the upper sliding rod 11, so that the upper sliding rod 11 and the lower sliding rod 1 can be driven to rotate simultaneously when the wind vane 13 rotates under the action of wind force.

The lower end of the lower sliding rod 1 is connected with a plurality of sliding seats 5 in a sliding mode, the sliding seats 5 are connected with a wind vane 13 through pull ropes 9, the sliding seats 5 are hinged to supporting rods 8 through supporting rods 6, elastic cloth is connected between the adjacent supporting rods 8, the upper ends of the supporting rods 8 are hinged to the outer wall of the lower sliding rod 1, and the sliding seats 5 are connected with the lower sliding rod 1 through reset springs 7.

The elastic cloth has waterproof performance, a layer of waterproof coating can be coated on the outer side of the elastic cloth, water is prevented from being adhered to the elastic cloth, accordingly, the overall quality of the elastic cloth becomes heavy, and the elastic cloth can be opened along with the opening of the supporting rod 8, so that the effect of balancing wind and wave thrust is achieved.

A plurality of groups of sliding grooves 17 are formed in two ends of the lower sliding rod 1, each group of sliding grooves 17 comprises two sliding grooves 17 symmetrically arranged on two sides of the lower sliding rod 1, sliding seats 5 are connected in the two sliding grooves 17 in a sliding mode, and the two sliding seats 5 are symmetrically arranged on two sides of the lower sliding rod 1.

Cavities 18 are formed in the lower sliding rod 1 and the upper sliding rod 11, the sliding grooves 17 are communicated with the cavities 18, a connecting plate 20 is connected between the sliding seats 5, and the connecting plate 20 is in sliding connection with the sliding grooves 17.

A spring fixing plate 19 fixedly connected with the inner wall of the lower sliding rod 1 is arranged in the cavity 18, the return spring 7 is arranged in the cavity 18 in a sliding mode, the upper end of the return spring 7 is connected with the spring fixing plate 19, and the lower end of the return spring 7 is connected with the connecting plate 20.

The wind vane 13 is connected with the pull rope 9 in a sliding way through a pull rope connecting plate 12, a plurality of supporting wheels 14 are arranged in the cavity 18 in a rotating way, the pull rope 9 is hung on the supporting wheels 14, and the pull rope 9 penetrates through a spring fixing plate 19 and then is connected with a connecting plate 20.

Wherein, the supporting wheel 14 can be provided with a plurality of, and the supporting wheel 14 rotates with lower sliding rod 1 or upper sliding rod 11 inner wall and is connected, and the supporting wheel 14 plays the effect of direction to stay cord 9, prevents that stay cord 9 and lower sliding rod 1 or upper sliding rod 11 inner wall from taking place the friction condition.

The upper end of bracing piece 8 is passed through fixing base 10 and is articulated with lower sliding rod 1, and fixing base 10 and 1 outer wall fixed connection of lower sliding rod, bracing piece 8 and fixing base 10 are articulated.

The pull rope 9 is slidably connected with the spring fixing plate 19, so that when the pull rope 9 rises, the pull rope can simultaneously drive the connecting plates 20 in the lower sliding rod 1 to simultaneously move upwards, and then the supporting rod 8 is driven to rotate around the fixing seat 10 through the supporting rod 6.

The lower sliding rod 1 is connected with rotating discs 15, a floating ball 16 is arranged between the rotating discs 15, and the floating ball 16 is rotationally connected with the rotating discs 15.

The rotating disc 15 has a limiting function on the floating ball 16, and prevents the floating ball 16 from sliding along the lower sliding rod 1 in the up-and-down direction.

The invention also provides a using method of the buoy device applied to water conservancy monitoring, which further comprises the following steps:

s1, placing the buoy 3 on the water surface to be monitored, adjusting a plurality of wind direction wind vanes 13 to be in the downwind direction under the action of wind along with the blowing of wind, and simultaneously driving the lower sliding rod 1 to rotate around the floating ball 16 by the wind direction wind vanes 13;

s2: the wind vane 13 is driven to slide along the upper sliding rod 11 along with the blowing of wind, the wind vane 13 drives the sliding seat 5 to slide upwards along the lower sliding rod 1 through the pull rope 9, the sliding seat 5 drives the supporting rod 8 to be opened through the supporting rod 6, and therefore the elastic cloth between the supporting rods 8 is driven to be opened, and the thrust of wind waves is balanced.

The windward side of the lower sliding rod 1 forms an obtuse angle with the wind waves, when the wind force is reduced, the sliding seat 5 slides downwards along the lower sliding rod 1 under the action of the return spring 7, so that the opening range of the supporting rods 8 is reduced, and the opening degree of the elastic cloth between the supporting rods 8 is further reduced.

It should be noted that, a plurality of floating ball 16 and wind vane 13 that set up, under the effect of buoyancy ball 16, it floats on the surface of water to drive wind vane 13, under the effect of sea wind, 4 wind vane 13 all rotate the adjustment and are the downwind direction, and then drive corresponding lower slide bar 1 and rotate, make all lower slide bar 1's windward side all be the obtuse angle with the stormy wave contained angle, thereby there is better support capacity, and is rational in infrastructure, according to the change of following the wind direction, the angle of 8 pivoted angles of automatically regulated bracing piece, thereby there is better stormy wave resistance, and economic and practical, and has high spreading value.

In addition, the arranged wind vane 13 can slide along the upper sliding rod 11 under the action of wind waves, the sliding seat 5 is driven to slide through the pull rope 9, and then the supporting rod 8 is driven to open through the supporting rod 6, so that the elastic cloth is opened, the thrust of the waves can be balanced when the wind waves come, the overturning phenomenon is reduced, the vibration of the buoy 3 is reduced, the opened size of the elastic cloth changes along with the size of the wind force, when the wind force is large, the opening range is large, the balance effect of the thrust of the wind waves is facilitated, the buoy 3 is enabled to be stable all the time, the shaking is reduced, the damage phenomenon of the buoy 3 is effectively prevented, the service life of the buoy 3 is prolonged, and the monitoring quality of the monitoring device is improved.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. The buoy device applied to water conservancy monitoring comprises a buoy (3) and is characterized in that the buoy (3) is connected with a plurality of floating balls (16), the floating balls (16) are rotatably connected with lower sliding rods (1) arranged in the inclining direction, the lower sliding rods (1) penetrate through the floating balls (16), the upper ends of the lower sliding rods (1) are connected with upper sliding rods (11), and the upper sliding rods (11) are slidably connected with wind vanes (13); lower slide bar (1) lower extreme sliding connection has a plurality of sliding seat (5), a plurality of sliding seat (5) all through stay cord (9) with wind vane (13) link to each other, sliding seat (5) articulate through vaulting pole (6) has bracing piece (8), and is adjacent be connected with elasticity cloth between bracing piece (8), bracing piece (8) upper end with lower slide bar (1) outer wall is articulated, sliding seat (5) through reset spring (7) with lower slide bar (1) links to each other.

2. The buoy device applied to water conservancy monitoring according to claim 1, wherein a plurality of groups of sliding grooves (17) are formed in two ends of the lower sliding rod (1), each group of sliding grooves (17) comprises two sliding grooves (17) symmetrically arranged on two sides of the lower sliding rod (1), the sliding seats (5) are connected in the two sliding grooves (17) in a sliding mode, and the two sliding seats (5) are symmetrically arranged on two sides of the lower sliding rod (1).

3. The buoy device applied to water conservancy monitoring of claim 2, wherein cavities (18) are formed in the lower sliding rod (1) and the upper sliding rod (11), the sliding grooves (17) are communicated with the cavities (18), a connecting plate (20) is connected between the sliding seats (5), and the connecting plate (20) is in sliding connection with the sliding grooves (17).

4. The buoy device applied to water conservancy monitoring according to claim 3, wherein a spring fixing plate (19) fixedly connected with the inner wall of the lower sliding rod (1) is arranged in the cavity (18), the return spring (7) is arranged in the cavity (18) in a sliding mode, the upper end of the return spring (7) is connected with the spring fixing plate (19), and the lower end of the return spring (7) is connected with the connecting plate (20).

5. The buoy device applied to water conservancy monitoring according to claim 4, wherein the wind vane (13) is slidably connected with the pull rope (9) through a pull rope connecting plate (12), a plurality of supporting wheels (14) are rotatably arranged in the cavity (18), the pull rope (9) is hung on the supporting wheels (14), and the pull rope (9) penetrates through the spring fixing plate (19) and then is connected with the connecting plate (20).

6. The buoy device applied to water conservancy monitoring according to claim 1, characterized in that the lower sliding rod (1) is connected with rotating discs (15), the floating ball (16) is arranged between the rotating discs (15), and the floating ball (16) is rotatably connected with the rotating discs (15).

7. The buoy device applied to water conservancy monitoring of claim 1, wherein the buoy (3) is connected with the floating balls (16) through a pull rod (2), and the number of the floating balls (16) is four; a detecting instrument is arranged in the buoy (3), and the buoy (3) is further connected with a solar panel (4).

8. The buoy device for water conservancy monitoring as claimed in claim 1, wherein the included angle between the lower slide rod (1) and the upper slide rod (11) is an acute angle.

9. A method for using a buoy device for water conservancy monitoring, which is characterized in that the buoy device for water conservancy monitoring as claimed in any one of claims 1 to 8 is adopted, and comprises the following steps:

s1, placing the buoy (3) on the water surface to be monitored, adjusting a plurality of wind vanes (13) to be in the downwind direction under the action of wind force along with the blowing of wind, and simultaneously driving the lower sliding rod (1) to rotate around the floating ball (16) by the wind vanes (13);

s2: the wind vane (13) is driven to slide along the upper sliding rod (11) along with the blowing of wind, the wind vane (13) drives the sliding seat (5) to slide upwards along the lower sliding rod (1) through the pull rope (9), and the sliding seat (5) drives the supporting rod (8) to be opened through the supporting rod (6), so that the elastic cloth between the supporting rods (8) is driven to be opened, and the thrust of wind waves is balanced.

10. The use method of the buoy device applied to water conservancy monitoring according to claim 9, wherein an included angle between the windward side of the lower sliding rod (1) and wind waves is an obtuse angle, and when the wind force is reduced, the sliding seat (5) slides downwards along the lower sliding rod (1) under the action of the return spring (7), so that the opening range of the supporting rods (8) is reduced, and the opening degree of the elastic cloth between the supporting rods (8) is reduced.

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