CN115126642B - Hydrologic monitoring station power supply based on coordinated energy storage of multiple power generation modes - Google Patents

Abstract

The application discloses a hydrologic monitoring station power supply based on coordinated energy storage of multiple power generation modes, and particularly relates to the field of hydrologic monitoring station power supplies. The application has the advantages of automatically adjusting the depth of the hydroelectric generation rotating blades, cleaning accumulated weeds around the hydroelectric generation rotating blades, continuously carrying out hydroelectric generation and continuously supplying electric energy.

Description

Hydrologic monitoring station power supply based on coordinated energy storage of multiple power generation modes

Technical Field

The application relates to the technical field of hydrologic monitoring station power supplies, in particular to a hydrologic monitoring station power supply based on coordinated energy storage of various power generation modes.

Background

The outdoor hydrologic monitoring station is generally provided with wind, light power generation and energy storage devices as a power supply mode, and part of monitoring stations cannot work all weather or for a long time due to the periodicity and uncertainty of wind and light power generation. Aiming at the characteristics of the working environment of the hydrologic monitoring station, the device mainly uses hydroelectric generation as a main power generation mode or wind-solar power generation, and can continuously transmit power to equipment and a power supply by depending on the relative stability of water flow.

However, the existing hydrologic monitoring station power supply can not effectively operate, particularly, when the water level is reduced, the bottom end of the hydroelectric generator can not be effectively connected with water flow, meanwhile, as weeds in water are more, the weeds are easy to wind on the rotating blades, the rotating blades can not rotate or rotate slowly, so that the power generation efficiency is affected, the rotating depth of the fan blades can be automatically adjusted, meanwhile, the weeds around the rotating blades can be automatically cleaned, so that the rotating blades can be guaranteed to normally operate, the hydroelectric generator can efficiently generate power, and the continuous supply of the power is kept.

Disclosure of Invention

In order to overcome the defects in the prior art, the embodiment of the application provides a hydrological monitoring station power supply which coordinates and stores energy based on various power generation modes, and the water level is automatically judged, so that the depth of a rotating blade in water is automatically adjusted, weeds around the rotating blade can be intermittently cleaned, and the problems in the background art are solved.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a hydrologic monitoring station power based on energy storage is coordinated to multiple power generation mode, includes the basic station, the basic station is provided with the door of entering, wind power generation pole is installed on the basic station top, wind power generation pole top supports and installs wind power generation fan blade, solar cell panel has been placed on the basic station of wind power generation pole bottom both sides, degree of depth adjustment mechanism is installed to the basic station bottom, degree of depth adjustment mechanism bottom is provided with the base, base one side is provided with the water depth detection subassembly, the fence is installed to the basic station bottom of degree of depth adjustment mechanism one side, install clean mechanism on the fence, clean mechanism supports by degree of depth adjustment mechanism, and reset assembly is installed to clean mechanism both sides.

In a preferred embodiment, the depth adjustment mechanism comprises a motor, the motor being mounted within a base station;

the top end of the coupler is connected with the motor;

the top end of the screw rod is connected with the bottom end of the coupler;

the two guide rails are arranged on two sides of the screw rod, the top end of the guide rail is fixedly arranged at the bottom of the base station, and the bottom end of the guide rail is arranged on the base;

the sliding block is sleeved on the screw rod, and two sides of the sliding block are in sliding connection with the guide rail;

the support plate is welded on one side of the sliding block;

the hydroelectric power generation rotating blade is arranged on the support plate, one side of the hydroelectric power generation rotating blade is provided with a swinging component, and the swinging component is connected with the cleaning mechanism;

the bearing frame, the bearing frame top supports the screw rod bottom, and bottom fixed mounting is on the base.

In a preferred embodiment, the cleaning mechanism comprises a connecting plate, and one end of the connecting plate is welded with the top of one side of the sliding block;

the sleeve hole is formed in the connecting plate, and a railing of the baffle is inserted in the sleeve hole in a sliding manner;

the bracket is welded at the other end of the connecting plate;

the two cassettes are arranged at two ends of the bracket, and reset components are arranged in the cassettes;

the two cleaning plates are respectively connected to one side of the corresponding reset component, are parallel to the baffle, and are positioned outside the baffle;

the two power plates are respectively connected to the other side of the corresponding reset component, are parallel to the baffle, are positioned on the inner side of the baffle, and are respectively engaged and matched with the swinging component.

In a preferred embodiment, the water depth detection assembly comprises a communicating pipe, wherein the communicating pipe is arranged on the base, and the bottom end of the communicating pipe is uniformly provided with through holes;

the top end of the traction rope is connected inside the base station;

the buoyancy ball is suspended in the communicating pipe and is connected with the bottom end of the traction rope.

In a preferred embodiment, the reset assembly comprises a rotating rod, and two ends of the rotating rod are respectively connected with the cleaning plate and the power plate;

the fixing sleeve is sleeved at the middle part of the rotating rod;

and the two reset springs are sleeved on the rotating rods at two sides of the fixed sleeve and are connected with the fixed sleeve.

In a preferred embodiment, the base station is internally provided with a controller, and the controller is electrically connected with the water depth detection assembly and the depth adjusting mechanism.

In a preferred embodiment, the base station internally mounted has wind power generation assembly, wind power generation assembly is connected with wind power generation pole and wind power generation fan blade, base station internally mounted has the battery, battery and solar cell panel and wind power generation assembly are electric connection, the battery is used for storing the electric energy that wind power generation assembly and solar cell panel produced, and is electric connection with the controller.

In a preferred embodiment, the height of the buoyancy ball is always 30cm higher than the top end of the hydroelectric generation rotating blade, and a limiting block is arranged at the bottom end of the screw rod.

In a preferred embodiment, the swinging height of the cleaning plate is lower than the height of the bracket, so as to protect the cleaning plate and ensure the normal operation of the hydroelectric generation rotating blade.

The application has the technical effects and advantages that:

1. compared with the prior art, the solar energy and the wind energy generated by the environment can be utilized to convert the electric energy through the arrangement of the solar cell panel, the wind power generation assembly and the storage battery, and the electric energy is stored in the storage battery, so that the electric energy support is provided for the depth adjusting mechanism, and the use of the electric energy generated by the hydroelectric generation is saved;

2. through the arrangement of the water depth detection assembly and the depth adjusting mechanism, compared with the prior art, the water level can be automatically detected through the water depth detection assembly, when the water level is lowered, a signal can be automatically fed back to the controller, the controller controls the depth adjusting mechanism to operate, so that the hydroelectric power generation rotating blades are always in proper water level, the hydroelectric power generation can be continuously carried out, the occurrence of water level lowering and power generation interruption is avoided, meanwhile, the situation that the conventional manual adjustment of the depth of the hydroelectric power generation rotating blades is required is avoided, the labor and time consumed are saved, the adjustment efficiency is improved, and the hydroelectric power generation is continuously carried out;

3. through the arrangement of the hydroelectric power generation rotating blade, the swinging component and the cleaning mechanism, compared with the prior art, the hydroelectric power generation rotating blade rotates and can drive the swinging component to rotate, the swinging component provides kinetic energy support for the cleaning mechanism, so that the power plates at two ends drive the cleaning plates to swing on the surface of the baffle, and the cleaning plates clean weeds accumulated on the baffle, so that the baffle opposite to the hydroelectric power generation rotating blade is cleaner, water flow can smoothly flow through the baffle, and the hydroelectric power generation rotating blade can normally operate;

4. through the setting of clean mechanism and reset assembly, compare with prior art, when the swing assembly swing in-process breaks with the power board of both sides, reset spring on the reset assembly rebound for the bull stick turns back, thereby makes power board and the clean board that both ends are connected reset, with this is reciprocal, clean mechanism can keep off the fence continuously, makes hydroelectric power generation swivel leaf can normally rotate, and hydroelectric power generation goes on continuously.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present application.

Fig. 2 is a schematic view of a front view plane structure of the present application.

Fig. 3 is a schematic rear plan view of the present application.

Fig. 4 is a schematic side plan view of the present application.

Fig. 5 is a schematic structural view of the depth adjusting mechanism of the present application.

FIG. 6 is a schematic view of the water depth detection assembly of the present application.

Fig. 7 is a schematic structural view of the cleaning mechanism of the present application.

Fig. 8 is a schematic structural diagram of a reset assembly according to the present application.

The reference numerals are: 1. a base station; 2. a door; 3. a solar cell panel; 4. a wind power generation pole; 5. wind power generation fan blades; 6. a baffle; 7. a cleaning mechanism; 701. a connecting plate; 702. trepanning; 703. a bracket; 704. a cartridge; 705. a cleaning plate; 706. a power plate; 8. a base; 9. a depth adjustment mechanism; 901. a motor; 902. a coupling; 903. a screw; 904. a guide rail; 905. a slide block; 906. a support plate; 907. rotating blades for hydroelectric generation; 908. a bearing seat; 10. a water depth detection assembly; 1001. a communicating pipe; 1002. a traction rope; 1003. a buoyancy ball; 11. a swing assembly; 12. a reset assembly; 1201. a fixed sleeve; 1202. a return spring; 1203. and (5) rotating the rod.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

The utility model provides a hydrologic monitoring station power based on energy storage is coordinated to multiple power generation mode as shown in fig. 1-8, includes basic station 1, basic station 1 is provided with entrance door 2, wind power pole 4 is installed on basic station 1 top, wind power pole 4 top support is installed wind power fan blade 5, solar cell panel 3 has been placed on basic station 1 of wind power pole 4 bottom both sides, degree of depth adjustment mechanism 9 is installed to basic station 1 bottom, degree of depth adjustment mechanism 9 bottom is provided with base 8, base 8 one side is provided with the water depth detection subassembly 10, keep off fence 6 is installed to the basic station 1 bottom of degree of depth adjustment mechanism 9 one side, install cleaning mechanism 7 on the keep off fence 6, cleaning mechanism 7 is supported by degree of depth adjustment mechanism 9, and reset assembly 12 is installed to cleaning mechanism 7 both sides.

As shown in fig. 1, 2, 3, 4 and 5, the depth adjustment mechanism 9 includes a motor 901, and the motor 901 is installed in the base station 1;

a coupler 902, wherein the top end of the coupler 902 is connected with the motor 901;

the top end of the screw 903 is connected with the bottom end of the coupler 902;

two guide rails 904, each of the guide rails 904 is arranged on two sides of the screw 903, the top end of the guide rail 904 is fixedly arranged at the bottom of the base station 1, and the bottom end of the guide rail 904 is arranged on the base 8;

the sliding block 905 is sleeved on the screw 903, and two sides of the sliding block 905 are in sliding connection with the guide rail 904;

a support plate 906, wherein the support plate 906 is welded on one side of the sliding block 905;

a hydroelectric power generation rotating blade 907, wherein the hydroelectric power generation rotating blade 907 is arranged on a support plate 906, one side of the hydroelectric power generation rotating blade is provided with a swinging component 11, and the swinging component 11 is connected with the cleaning mechanism 7;

the bearing pedestal 908, the top of bearing pedestal 908 supports the bottom of screw 903, and the bottom fixed mounting is on base 8.

As shown in fig. 2, 3, 4 and 7, the cleaning mechanism 7 includes a connecting plate 701, and one end of the connecting plate 701 is welded to a top of one side of the slider 905;

a sleeve hole 702, wherein the sleeve hole 702 is arranged on the connecting plate 701, and a railing of the baffle 6 is inserted in the sleeve hole in a sliding manner;

a bracket 703, wherein the bracket 703 is welded at the other end of the connecting plate 701;

two cartridges 704, each of the cartridges 704 is disposed at two ends of the bracket 703, and a reset assembly 12 is installed inside the cartridge;

two cleaning plates 705, each cleaning plate 705 is connected to one side of the corresponding reset component 12, is parallel to the baffle 6, and is positioned outside the baffle 6;

the two power plates 706 are respectively connected to the other side of the corresponding reset component 12, are parallel to the baffle 6 and are positioned on the inner side of the baffle 6, and are respectively engaged with the swinging component 11.

As shown in fig. 3, 4 and 6, the water depth detection assembly 10 includes a communicating pipe 1001, the communicating pipe 1001 is mounted on the base 8, and the bottom end is uniformly provided with through holes;

a hauling cable 1002, wherein the top end of the hauling cable 1002 is connected inside the base station 1;

the buoyancy ball 1003 is suspended in the communicating pipe 1001 and connected with the bottom end of the hauling rope 1002.

As shown in fig. 7 and 8, the reset assembly 12 includes a rotating rod 1203, and two ends of the rotating rod 1203 are respectively connected with the cleaning plate 705 and the power plate 706;

the fixed sleeve 1201 is sleeved in the middle of the rotating rod 1203;

and two return springs 1202, wherein each return spring 1202 is sleeved on the rotating rod 1203 at two sides of the fixed sleeve 1201 and is connected with the fixed sleeve 1201.

As shown in fig. 1, the base station 1 is internally provided with a controller, and the controller is electrically connected with the water depth detection assembly 10 and the depth adjusting mechanism 9.

As shown in fig. 1, the base station 1 is internally provided with a wind power generation assembly, the wind power generation assembly is connected with the wind power generation pole 4 and the wind power generation fan blade 5, the base station 1 is internally provided with a storage battery, the storage battery is electrically connected with the solar panel 3 and the wind power generation assembly, and the storage battery is used for storing electric energy generated by the wind power generation assembly and the solar panel 3 and is electrically connected with the controller.

As shown in fig. 3 and 4, the height of the buoyancy ball 1003 is always 30cm higher than the top end of the hydroelectric generation rotating blade 907, and a limiting block is arranged at the bottom end of the screw 903.

As shown in fig. 2, the swing height of the cleaning plate 705 is lower than the height of the bracket 703, so as to protect the cleaning plate 705 and ensure the normal operation of the hydroelectric power rotating vane 907.

The working principle of the application is as follows: when the device works, the wind power generation assembly and the solar panel 3 on the base station 1 convert electric energy and store the electric energy in a storage battery, power support is provided for a controller connected with the depth adjusting mechanism 9 and the water depth detecting assembly 10, the water depth detecting assembly 10 detects the water level, feedback signals are fed back to the controller, and the controller controls the depth adjusting mechanism 9 to operate according to the electric quantity provided by the storage battery, so that the installed hydroelectric generation rotating blades 907 are positioned at proper depth in water and are continuously connected with water flow to perform hydroelectric generation;

when the hydroelectric generation rotating blade 907 rotates to convert electric energy, the connected swinging component 11 rotates, when the swinging component 11 rotates, the linked cleaning mechanism 7 automatically operates to clean weeds accumulated on the baffle 6, meanwhile, after the cleaning mechanism 7 operates, reset components 12 arranged at two ends of the cleaning mechanism 7 automatically reset the cleaning mechanism 7 when the cleaning mechanism 7 is disconnected from the swinging component 11, so that the weeds on the baffle 6 are intermittently cleaned, water flow is prevented from being blocked, and the hydroelectric generation rotating blade 907 normally rotates to continuously generate electricity;

specifically, when the water level is detected by the water depth detection assembly 10, water enters the communicating pipe 1001 from the bottom end of the communicating pipe 1001, so that the buoyancy ball 1003 floats on the water surface in the communicating pipe 1001, when the water level drops, the buoyancy ball 1003 drops, the traction rope 1002 stretches, and the controller controls the depth adjusting mechanism 9 to operate according to the stretching amount of the traction rope 1002;

when the depth adjusting mechanism 9 is operated, the controller controls the motor 901 to operate, so that the screw 903 connected with the coupling 902 rotates, the sliding block 905 on the screw 903 slides downwards under the assistance of the screw 903 and the guide rails 904 on the two sides, when the sliding depth is equal to the extension length of the traction rope 1002, the motor 901 stops, the hydroelectric power generation rotating blades 907 arranged on the support plate 906 welded on one side of the sliding block 905 also descends by the same depth, and the cleaning mechanism 7 connected with the sliding block 905 descends by the same distance;

when the hydroelectric generation rotating blades 907 run and perform electric energy conversion, the swinging component 11 is enabled to synchronously rotate, one end of the swinging component 11 is in pressure connection with the power plate 706 on one side, the other end of the swinging component 11 is in propping connection with the power plate 706 on the other side, and the two cleaning plates 705 connected with the resetting component 12 at the other end swing in opposite directions, so that weeds on the barrier 6 are removed, the barrier 6 opposite to the hydroelectric generation rotating blades 907 is in a clean state, and water flow can smoothly pass through;

when the swing assembly 11 swings and is disconnected from the power plates 706 at two sides, the reset spring 1202 on the reset assembly 12 bounces back, so that the rotating rod 1203 rotates back, and the power plates 706 and the cleaning plates 705 connected at two ends are reset.

The last points to be described are: first, in the description of the present application, it should be noted that, unless otherwise specified and defined, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be mechanical or electrical, or may be a direct connection between two elements, and "upper," "lower," "left," "right," etc. are merely used to indicate relative positional relationships, which may be changed when the absolute position of the object being described is changed;

secondly: in the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, and other structures can refer to the common design, so that the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict;

finally: the foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the application are intended to be included within the scope of the application.

Claims (3)

1. Hydrologic monitoring station power based on energy storage is coordinated to multiple power generation mode, including basic station (1), its characterized in that: the novel solar energy power generation system is characterized in that the base station (1) is provided with a household door (2), a wind power generation rod (4) is arranged at the top end of the base station (1), wind power generation blades (5) are supported and arranged at the top end of the wind power generation rod (4), solar panels (3) are placed on the base station (1) at two sides of the bottom end of the wind power generation rod (4), a depth adjusting mechanism (9) is arranged at the bottom end of the base station (1), a base seat (8) is arranged at the bottom end of the depth adjusting mechanism (9), a water depth detecting assembly (10) is arranged at one side of the base seat (8), a baffle (6) is arranged at the bottom end of the base station (1) at one side of the depth adjusting mechanism (9), a cleaning mechanism (7) is supported by the depth adjusting mechanism (9), and reset assemblies (12) are arranged at two sides of the cleaning mechanism (7);

the depth adjusting mechanism (9) comprises a motor (901), and the motor (901) is installed in the base station (1);

the top end of the coupler (902) is connected with the motor (901);

the top end of the screw rod (903) is connected with the bottom end of the coupler (902);

the two guide rails (904), each guide rail (904) is arranged on two sides of the screw (903), the top end of each guide rail is fixedly arranged at the bottom of the base station (1), and the bottom end of each guide rail is arranged on the base (8);

the sliding block (905) is sleeved on the screw rod (903), and two sides of the sliding block (905) are in sliding connection with the guide rail (904);

a support plate (906), wherein the support plate (906) is welded on one side of the sliding block (905);

the hydroelectric power generation rotating blade (907), the hydroelectric power generation rotating blade (907) is arranged on the support plate (906), one side of the hydroelectric power generation rotating blade is provided with the swinging component (11), and the swinging component (11) is connected with the cleaning mechanism (7);

the top end of the bearing seat (908) supports the bottom end of the screw rod (903), and the bottom end is fixedly arranged on the base (8);

the cleaning mechanism (7) comprises a connecting plate (701), and one end of the connecting plate (701) is welded with the top of one side of the sliding block (905);

the sleeve hole (702) is formed in the connecting plate (701), and a railing of the baffle (6) is inserted in the sleeve hole in a sliding manner;

a bracket (703), wherein the bracket (703) is welded at the other end of the connecting plate (701);

two cartridges (704), wherein each cartridge (704) is arranged at two ends of the bracket (703), and reset components (12) are arranged in the cartridges;

the two cleaning plates (705), each cleaning plate (705) is connected to one side of the corresponding reset component (12) respectively, is parallel to the baffle (6) and is positioned outside the baffle (6);

the two power plates (706), each power plate (706) is connected to the other side of the corresponding reset component (12) and is parallel to the baffle (6) and positioned on the inner side of the baffle (6), and meanwhile, the two power plates are respectively connected and matched with the swing component (11);

the water depth detection assembly (10) comprises a communicating pipe (1001), wherein the communicating pipe (1001) is arranged on the base (8), and through holes are uniformly formed in the bottom end of the communicating pipe;

the top end of the hauling rope (1002) is connected inside the base station (1);

the buoyancy ball (1003) is suspended in the communicating pipe (1001) and is connected with the bottom end of the hauling rope (1002);

the reset assembly (12) comprises a rotating rod (1203), and two ends of the rotating rod (1203) are respectively connected with the cleaning plate (705) and the power plate (706);

the fixing sleeve (1201) is sleeved at the middle part of the rotating rod (1203);

two return springs (1202), wherein each return spring (1202) is sleeved on a rotating rod (1203) at two sides of the fixed sleeve (1201) and is connected with the fixed sleeve (1201);

a controller is arranged in the base station (1), and the controller is electrically connected with the water depth detection assembly (10) and the depth adjusting mechanism (9);

the intelligent energy-saving wind power generation system is characterized in that a wind power generation assembly is arranged in the base station (1), the wind power generation assembly is connected with a wind power generation rod (4) and a wind power generation fan blade (5), a storage battery is arranged in the base station (1), the storage battery is electrically connected with the solar panel (3) and the wind power generation assembly, and the storage battery is used for storing electric energy generated by the wind power generation assembly and the solar panel (3) and is electrically connected with the controller.

2. The hydrological monitoring station power supply based on coordinated energy storage of multiple power generation modes according to claim 1, wherein: the buoyancy ball (1003) is always higher than the top end of the hydroelectric generation rotating blade (907) by 30cm, and a limiting block is arranged at the bottom end of the screw (903).

3. The hydrological monitoring station power supply based on coordinated energy storage of multiple power generation modes according to claim 1, wherein: the swing height of the cleaning plate (705) is lower than the height of the bracket (703), and the cleaning plate is used for protecting the cleaning plate (705) and guaranteeing the normal operation of the hydroelectric generation rotating blade (907).